(Received for publication, December 19, 1996, and in revised form, June 5, 1997)
From the Central Research and Development Department,
Experimental Station, E. I. du Pont de Nemours & Co.,
Wilmington, Delaware 19880-0173 and the ¶ Agricultural Products
Department, Stine-Haskell Research Center, E. I. du Pont de
Nemours & Co., Newark, Delaware 19714
Polypeptide D1 of the photosystem II reaction center of oxygenic photosynthesis is expressed in precursor form (pre-D1), and it must be proteolytically processed at its C terminus to enable assembly of the manganese cluster responsible for photosynthetic water oxidation. A rapid and highly sensitive enzyme-linked immunosorbent assay-based microtiter plate method is described for assaying this D1 C-terminal processing protease. A protocol is described for the isolation and purification to homogeneity of the enzyme from the green alga, Scenedesmus obliquus. Amino acid sequence information on the purified protease was used to clone the corresponding gene, the translated sequence of which is presented. A comparison of the gene product with homologous proteases points to a region of conserved residues that likely corresponds to the active site of a new class of serine protease. The LF-1 mutant strain of Scenedesmus (isolated by Dr. Norman Bishop) is incapable of processing pre-D1. We show here that the C-terminal processing protease gene in this strain contains a single base deletion that causes a frame shift and a premature stop of translation within the likely active site of the enzyme. A suppressor strain, LF-1-RVT-1, which is photoautotrophic and capable of processing pre-D1 has a nearby single base insertion that restores the expression of active enzyme. These observations provide the first definitive proof that the enzyme isolated is responsible for in vivo proteolytic processing of pre-D1 and that no other protease can compensate for its loss.
The photosystem II reaction center contains two homologous polypeptides, D1 and D2, that are responsible for the coordination of the primary photoreactants (1, 2). D1 has also been shown to harbor the redox-active tyrosine, TyrZ (3, 4), that links the oxidized primary electron donor of photosystem II to the oxygen-evolving manganese cluster and is thought to provide at least some of the coordinating ligands to this complex (5-8). D1 is expressed in precursor form (9-11), inserted into the thylakoid membrane, and processed at its C terminus (6, 12-15) by a proteolytic enzyme, D1 C-terminal processing protease (Ctp-protease).1 In cyanobacteria, 16 residues are cleaved from precursor D1 (6), 9 in higher plants (15, 16), and 8 in Chlamydomonas2 with processing occurring in all cases at the carboxyl side of D1-Ala-344. Euglena is the sole oxygenic photosynthetic organism that is believed not to undergo C-terminal processing (1), although, in this case, no C-terminal extension is present. Based on a comparison of 43 psbA genes, the amino acid sequence on the amino side of the processing site is strictly conserved within the 8 residues immediately upstream of the processing site (1). On the carboxyl side of the processing site, no residue is conserved throughout all 43 sequences. While position 345 is normally occupied by either an alanine or a serine, replacement of Ser-345 in Synechocystis 6803 with arginine or alanine (6) or in Chlamydomonas with glycine, cysteine, valine, or phenylalanine (17) still allows processing to proceed normally, in vivo.
The x-ray-induced, non-oxygen evolving LF-1 mutant strain of Scenedesmus obliquus was originally characterized by Metz and Bishop (20) as having little variable fluorescence, being unable to evolve oxygen and containing on a per chlorophyll basis in thylakoid membranes less than half the manganese of wild type. All of these characteristics imply an inability to assemble the manganese cluster. The LF-1 strain has been shown to be incapable of processing pre-D1 (13, 21, 22). This lack of processing has been attributed to the absence of the D1 Ctp-protease (13, 20-22). These observations led to the conclusion that proteolytic processing of precursor D1 is required for assembly of the manganese cluster (13, 21, 22) either because proteolytic cleavage frees the C-terminal carboxyl group of D1-Ala-344 to coordinate manganese (6) or because the presence of the C-terminal extension blocks the C-terminal region of D1 from adopting a conformation compatible with manganese coordination. This conclusion has been further reinforced by two experimental observations. A site-directed mutant of Synechocystis 6803, in which D1-Ser-345 was replaced by proline, lost the ability to process the D1 polypeptide and to assemble the manganese cluster (6). Furthermore, Shestakov and co-workers (23) have recently described a spontaneous mutant strain of Synechocystis 6803 with a point mutation in a gene that they have named ctpA. This strain and a strain in which ctpA was insertionally inactivated (24) are reported to be inactive for oxygen evolution and to show reduced mobility of polypeptide D1 on SDS-PAGE, consistent with a loss of processing (24).
The reason for the existence of the C-terminal extension remains
unclear, particularly as it is absent in Euglena and as
deletion from the 3 end of the psbA gene through codon 345 in Synechocystis (6) and Chlamydomonas (18, 19)
still results in the assembly of a functional manganese
cluster. The rate of growth of the Synechocystis mutant is,
however, far more inhibited than wild type at high light intensities
where rapid replacement of impaired photosystem II reaction centers is
required to keep pace with photoinactivation. This observation implies
some facilitation by the C-terminal extension of reaction center or
manganese cluster assembly. Deletion of only one amino acid residue
further, through codon 344 in Synechocystis (6), results in
a total loss of oxygen activity, consistent with a role for C-terminal
D1-Ala-344 in manganese coordination.
Bowyer and collaborators (25) have reported crude isolates of D1 Ctp-protease from pea and wild type Scenedesmus that catalyze C-terminal processing of the D1 polypeptide in thylakoid membranes isolated from the Scenedesmus LF-1 strain, rendering the thylakoid membranes photoactivable for water oxidation. Satoh and co-workers (26), in a very thorough effort, have recently isolated and purified D1 Ctp-protease from spinach. This enzyme was partially sequenced and the gene that encodes it cloned and fully sequenced (27). The lumenal location of this protease is indicated by the need for sonication (26) or detergent treatment (see below) to free the water-soluble enzyme from the thylakoid membranes and by the presence of a lumenal transit peptide (27). This localization and the substrate specificity (28) of the enzyme are both consistent with its being the D1 Ctp-protease, the substrate of which is also located in the lumen (29). However, no mutational test, showing this enzyme to function in vivo as D1 Ctp-protease, has as yet been reported. While the translated spinach gene does show homology (42.2% identity, (27)) to the ctpA gene mentioned above, there exists no direct in vitro demonstration that the ctpA gene product of Synechocystis has D1 Ctp-protease activity.
In this paper, we report the development of a sensitive microtiter plate ELISA assay for D1 Ctp-protease. By using this assay to monitor the activity of this enzyme from the green alga, Scenedesmus obliquus, we report the isolation, purification, and amino acid sequencing of its D1 Ctp-protease. This enzyme shows the expected cleavage site specificity using a synthetic peptide as substrate. We have exploited the amino acid sequence information, obtained from the purified enzyme, to clone and sequence the D1 Ctp-protease genes from the Scenedesmus wild type, from the non-photoautotrophic LF-1 strain, and from a photoautotrophic LF-1 suppressor strain (LF-1-RVT-1). We show that the loss of D1 processing in LF-1 can be explained by a single base pair deletion in the coding region of the gene, causing a frame shift and a premature translational termination. Restoration of D1 processing and photoautotrophy in the suppressor strain is correlated with a nearby single base pair insertion. We present, therefore, the first definitive proof that an enzyme that functions as D1 Ctp-protease in vitro is also responsible for in vivo proteolytic processing of pre-D1.
Algal Strains
The algal strains used in this study were the wild type of S. obliquus, strain D3, and a non-photosynthetic low fluorescent mutant (LF-1), derived from wild type by x-ray mutagenesis (20). A photoautotrophic suppressor strain, derived from LF-1 (LF-1-RVT-1) (31), was also examined. All strains were kindly provided by Dr. Norman Bishop (Oregon State University, Corvallis, OR). Except where fermentors were used, the cells were grown in 20-liter carboys on NGY medium (30) in the light at 25 °C.
Preparation of Primary Antibody
A synthetic peptide (EVMHERNAHNFPLDLA), identical to the final
16 residues of practically all known sequences of polypeptide D1 (1),
was synthesized (>95% pure, Multiple Peptide Systems) and coupled to
keyhole limpet hemocyanin by using glutaraldehyde at a 1:1 ratio of
peptide to keyhole limpet hemocyanin (w/w). New Zealand White rabbits
were immunized using the peptide-keyhole limpet hemocyanin conjugate
suspended in phosphate-buffered saline buffer (3.1 mg/ml) and
emulsified by mixing with an equal volume of Freund's adjuvant and
injected into 5-6 subcutaneous dorsal sites for a total volume of 0.6 ml. The initial immunization was followed by three booster injections
21 days apart. The antiserum that was used as primary antibody in the
assays was obtained from one rabbit 10 days after the second booster
injection. The animals were bled from the ear vein. The blood was
heated to 37 °C for 1 h, chilled to 0 °C for 15 h, and
centrifuged. Further purification of the immunoglobulins was not
attempted. The serum was frozen and stored at 80 °C.
Microtiter Plate Assay of D1 Protease
The ELISA based assay for the detection of D1 Ctp-protease activity detects product formation very specifically, by the use of the above-mentioned primary antibody that associates to at least 30-fold greater extent to the product than to the substrate. In practice, the ratio of signals for processed PSII cores of wild type to unprocessed PSII cores of LF-1 is usually 15-30. Substrate core complexes are linked to a 96-well microtiter plate; D1 Ctp-protease is added to the wells for a fixed time, and the product is analyzed by using the primary antibody followed by an enzyme-linked secondary antibody. The quantity of primary antibody attached to the product of the D1 Ctp-protease reaction is detected through the alkaline phosphatase conjugate of the secondary antibody, and the alkaline phosphatase activity is measured colorimetrically to quantify protease activity.
Preparation of Microtiter PlatesPSII core complexes were
isolated from Scenedesmus wild type and LF-1 as described by
Diner et al. (13) and stored at 80 °C. Immediately
before use, they were diluted to 2 ng of chlorophyll/µl using TBS (20 mM Tris-HCl, pH 8.0, 150 mM NaCl). Each plate
requires 5 µg of chlorophyll or 2.5 ml of diluted LF-1 cores and 0.2 µg of chlorophyll or 100 µl of wild type cores. Ten plates were
typically prepared at the same time.
Fresh glutaraldehyde (25% solution, Electron Microscopy Sciences, EM grade, Fort Washington, PA) was diluted to 0.5% with TBS immediately before use, and 25 µl of the diluted glutaraldehyde was pipetted into each well of a 96-well microtiter plate (Nunc Immunoplate Maxisorp, catalog number 439454). 25 µl of the diluted LF-1 cores were pipetted per well into all but three wells of the plate, and the plate was shaken to mix the glutaraldehyde and the core complexes. 25 µl of the diluted wild type cores were pipetted per well into each of the remaining three wells, and the plates were shaken for 1-2 h at room temperature.
At the end of the incubation period, the wells were washed to remove
unbound core complexes and blocked to prevent nonspecific protein
binding. Both were accomplished with four rinses with TTBS (50 mM Tris-HCl, pH 7.4, 150 mM NaCl, 0.2% Tween
20) and then filling each well with TTBS. The plates were then
incubated for 1-2 h at room temperature, after which the wells were
again rinsed. The remaining TTBS was aspirated and shaken out of the wells. The plates were then sealed in plastic bags containing a
moistened paper towel. The plates were then stored at 20 °C and
could be used for several months. However, the background signal in
blank wells lacking enzyme gradually increased with storage time.
D1 Ctp-protease preparations were diluted to 50 µl with 20 mM HEPES-KOH, pH 7.25, 20% glycerol (assay buffer) and placed in individual assay wells. Usually only rows B-G and columns 2-11 were used for assaying enzyme activity because the wells at the periphery of the plate often gave slightly higher signals. The control wells (located in column 12) were not incubated with protease and thereby show the maximum (wild type wells) and minimum (LF-1 wells) signals attainable with the D1 ELISA assay. The samples of D1 protease were typically allowed to incubate for 1 h at room temperature after which each well was given three quick rinses with TTBS and then allowed to soak for 2 min. The TTBS was aspirated, and the wells were refilled without rinsing for another 2 min incubation. This wash/incubation was repeated one more time. The plate was then aspirated dry and turned over to tap any remaining buffer onto a paper towel.
5 µl of primary antibody serum was diluted with 5 ml of phosphate-buffered saline (1.44 g of Na2HPO4, 0.24 g of KH2PO4, pH 7.2, 8 g of NaCl. 0.2 g of KCl, and 20 g of bovine serum albumin per liter), previously filter sterilized through a 0.2-µm membrane. 50 µl of diluted primary antibody solution was added to each well. The plates were covered and allowed to incubate on a rotary shaker at 37 °C. After 30 min, the plate was washed as above with three cycles of soak and aspiration using TTBS.
10 µl of goat anti-rabbit IgG conjugated to alkaline phosphatase (Sigma Immunochemicals A-7539) were diluted into 5 ml of TBS (3 g of Tris-HCl, pH 8.0, 8 g of NaCl, 0.2 g of KCl, and 20 g of bovine serum albumin per liter), previously filter sterilized through a 0.2-µm membrane. 50 µl of diluted secondary antibody solution was added to each well, and the covered plates were allowed to incubate on a rotary shaker at 37 °C. After 30 min, the plate was washed three times with TTBS as above.
The colorimetric substrate consisted of one 5-mg tablet of
p-nitrophenyl phosphate (Kirkegaard & Perry Laboratories)
dissolved in 5 ml of 5 × diluted DEA Buffer (Kirkegaard & Perry
Laboratories). 50 µl of this solution was added to each well, and the
plate was incubated at 37 °C in a microtiter plate reader (Molecular
Devices Thermomax) interfaced to a Macintosh SE/30 computer. The
increase in the concentration of p-nitrophenol was typically
determined by monitoring the increase in absorption at 405 minus 650 nm
for 10 min. Activity is expressed as milli-OD/min. Alternatively the
plates were incubated at 37 °C for 1 h and measured by the same
wavelength difference after quenching the reaction with 50 µl of 3 M NaOH per well. The extent of cleavage of the D1
polypeptide in the test well could be determined by comparison with the
control LF-1 and wild type wells that had not been incubated with
enzyme. The ratio of the signals from these wells were usually
1:15-30, respectively, indicating that the primary antibody directed
against the mature C terminus has a much reduced affinity for the
preprocessed C terminus of the D1 polypeptide.
An example of the dependence of the assay on enzyme concentration is
shown in Fig. 1 where the intensity of
the color reaction is shown to be proportional to enzyme concentration
up to approximately 20% pre-D1 cleaved. The assay is also linear with
time (Fig. 2) up to approximately the
same percentage of cleaved pre-D1.
Fig. 3 shows the pH dependence of enzyme
activity for Scenedesmus D1 Ctp-protease. A pH optimum is
observed at pH 6.3. The enzyme activity drops rapidly as the pH is
lowered, registering zero at pH 4.1.
Purification of Scenedesmus D1 Protease
Protease ExtractionWild type cells of S. obliquus cells were grown on NGY medium in a 200-liter fermentor
to an A600 nm of about 6 (2-4 days) at which
point the culture was harvested. Cells from the fermentor were
suspended in 1 volume per weight of 20 mM HEPES-KOH, 10 mM KCl, 10% glycerol, and pH 7.25 (buffer H), and
centrifuged 5 min at 5000 rpm (4200 × g) in a Sorvall
GS-3 rotor. The pelleted cells were resuspended in 1 volume per weight
in buffer H and stored at 80 °C until use. For a typical protease
isolation, 1 liter of cell suspension was thawed and processed through
a microfluidizer (model 110Y; Microfluidics Corp., Newton, MA) by using
four passes (18,000-23,000 p.s.i.) with cooling in a wet ice bath
between passes. The homogenate was centrifuged 10 min at 16,000 × g in a Sorvall GSA rotor to remove cell debris. The pellet
was washed with buffer H to resuspend sedimented thylakoids and was
added to the supernatant. The combined slurry was homogenized by
stirring 30 min or by using a Teflon/glass homogenizer. Thylakoids were
collected by centrifuging 2 h (or overnight) in Beckman 45Ti rotors at 235,000 × g. The pelleted thylakoids were
resuspended in buffer H by using a Teflon/glass homogenizer and brought
to a concentration of 2 mg of chlorophyll/ml and 0.5% by volume Triton X-100 from a 20% aqueous stock. After stirring for 30 min, the thylakoids were centrifuged for 2 h at 235,000 × g in a 45 Ti rotor. The Triton X-100 supernatant was
collected and stored on ice. The thylakoid pellet was resuspended in
buffer H and brought to 2 mg/ml chlorophyll and 0.5% Triton X-100.
After stirring 30 min it was centrifuged 2 h in a 45 Ti rotor at
45,000 rpm (235,000 × g).
The second Triton X-100 supernatant was combined with the first and loaded onto a 5 × 35-cm column of hydroxylapatite (Fast flow, Calbiochem) that had been previously equilibrated with 10 mM K2HPO4/KH2PO4, pH 7.0, 10% glycerol. After loading (10 ml/min), the column was washed with 500 ml of equilibration buffer, and 250-ml fractions were collected. This was followed by 1 liter of 100 mM K2HPO4/KH2PO4, pH 7.0, and 10% glycerol, and 50-ml fractions were collected and assayed undiluted using the microtiter plate assay. All of the above steps, following cell breakage, were performed at 4 °C.
The active fractions (200-300 ml) were concentrated over an Amicon YM-10 ultrafilter to about 50 ml and then diluted and reconcentrated twice in 20 mM HEPES-KOH, pH 7.25, 20% glycerol to drop the phosphate concentration about 10-fold. The sample was brought to a final volume of 21.75 ml to which there was added 6.25 ml of saturated-neutralized ammonium sulfate to give a final concentration of 1 M (NH4)2SO4. The suspension was left on ice for 0.5-1 h and then spun at 10,000 × g to remove precipitate. The supernatant was then filtered by using a 0.45-µm Acrodisc membrane (Gelman Sciences).
Hydrophobic Interaction ColumnThe hydrophobic interaction
column (TSK-Gel Phenyl-5PW, 20-mm inner diameter × 15 cm, TosoHaas)
was preceded by a guard column of the same material (20-mm inner
diameter × 2 cm). The column was first washed at 3 ml/min for 20-30
min with buffer B (20 mM HEPES-KOH, pH 7.25, and 20%
glycerol) and then equilibrated at 10 °C with 60% buffer A (20 mM HEPES-KOH, pH 7.25, and 20% glycerol plus 2 M (NH4)2SO4), 40%
buffer B at the same flow rate for 30-40 min. The buffers had been
previously filtered through 0.45-µm membranes. The sample was loaded
onto the hydrophobic interaction column at 3 ml/min by using a
Pharmacia Superloop. The buffer mixture was maintained at 60% A:40% B
for 25 min, sufficient to empty the Superloop and to wash out unbound
protein (Fig. 4). A linear gradient was
then applied at 3 ml/min which went from 60% A:40% B to 20% A:80% B
over the next 90 min. The run was completed by ramping up to 100% B
over the following 20 min and maintained at that level for another 15 min. Three-ml fractions were collected. The eluant was assayed by
diluting aliquots of the column fractions 1:4 to 1:10 with buffer B
(assay buffer). The peak of enzyme activity appeared at a point where
67% buffer B was entering the column (0.67 M
(NH4)2SO4, 85 min into the run).
After each use the hydrophobic interaction column was equilibrated with
water, given four 1-ml pulses with 0.2 M NaOH, and then
reequilibrated with water.
Active fractions from the hydrophobic interaction column were pooled
and concentrated by using a Centriprep 10 (Amicon) to 3 ml and passed
through an Econo-Pac10 DG desalting column (Bio-Rad) previously equilibrated with buffer B and used according to the manufacturer's instructions.
The approximate 4-ml sample was then loaded
onto an HR10/10 MonoQ column (Pharmacia Biotech Inc.) at a flow rate of
1 ml/min, previously equilibrated with buffer B. The column was
subsequently washed for 10 min with 100% buffer B followed by a linear
gradient from 100% buffer B to 100% buffer C (buffer B plus 0.5 M NaCl) over a period of 100 min and maintained at 100%
buffer C for 10 min, all at a flow rate of 1 ml/min (Fig.
5). 2-ml fractions were collected.
Aliquots of each fraction were diluted 1:4 with buffer B and assayed.
The peak of activity typically appeared at a position in the gradient
where 28% buffer C (0.14 M NaCl) was entering the column
(38 min into the run).
Isoelectric Focusing
Preparative isoelectric focusing was carried out in a Bio-Rad Rotofer cell using 45 ml of 20% glycerol, 0.1% CHAPS, 1% Servalyte 4-6, and 0.25% Servalyte 3-10. The cell was prerun for 1 h at 12 watts to establish the pH gradient and following the addition of 4 ml of sample to the center well subsequently run for 3-4 h at 5 °C at 12 watts. Peak protease activity corresponded to fractions with an isoelectric point of 5.0 ± 0.2.
Gel Filtration ColumnThe active Rotofer fractions were
concentrated to about 50 µl by using a Centricon 10 (Amicon) and
injected onto a TSK-Gel G4000SWXL column (8-µm particle size, 7.8 mm
inner diameter × 60 cm) previously equilibrated with buffer D (buffer
B plus 100 mM NaCl). The column was run at 0.25 ml/min, and
0.5-ml fractions were collected (Fig. 6).
Aliquots of each fraction were diluted 1:4 or 1:6 with buffer B and
assayed with peak activity eluting at 92 min. A TSK G3000SW column
(7.5-mm inner diameter × 60 cm) was also used on occasion and run
under the same conditions. The peak of activity in this case appeared
at 66 min into the run. The active fractions were pooled and
concentrated by using a Centricon 10 (Amicon) to about 50 µl and
stored at 80 °C.
All of the above column steps were performed at 10 °C.
Preparation of Purified Enzyme for Amino Acid Sequencing
SDS-PAGE and blotting were carried out according to Ref. 32.
Solubilization buffer (0.2 M sucrose, 6% SDS, 125 mM Tris, 4 mM EDTA, 0.04% bromphenol blue, and
2% -mercaptoethanol (v/v) adjusted to pH 6.9) was added to an equal
volume of concentrated D1 Ctp-protease and loaded onto the sample well
of the polyacrylamide gel. SDS-PAGE with 12% polyacrylamide gels were
run at room temperature according to Laemmli (42) with the upper buffer
chamber containing 0.2% SDS and 0.1 mM thioglycolate. Gels
were then soaked for 25 min in transfer buffer composed of 10 × Towbin buffer (250 mM Tris, 1.92 M glycine) + 400 ml of MeOH diluted to 4 liters with Milli-Q water. Bio-Rad
TransBlot polyvinylidene difluoride membrane (0.2 µm) was soaked
10 s in methanol and then 20 min in transfer buffer. Blotting was
carried out in a Bio-Rad liquid Trans-Blot Cell using the above
indicated transfer buffer and according to the manufacturer's
instructions at 240 mA for 3 h at room temperature. The blot was
washed three times for 5 min each with Milli-Q water and then stained
for 1 min with 0.1% amido black in 10% acetic acid in Milli-Q water.
The blot was destained for 1 min with 5% aqueous acetic acid and
washed thoroughly with Milli-Q water. The blot was air-dried and sent
for sequencing to the Wistar Protein Microchemistry Laboratory
(Philadelphia, PA). Tryptic digest of the protein on the blot and
subsequent HPLC purification of the tryptic fragments were performed as
described in Ref. 32. Edman sequencing was conducted at both the N
terminus and on selected HPLC-purified tryptic fragments. In the latter
case the MALDI (matrix-assisted laser desorption ionization) mass
spectra were also obtained on the sequenced fragments as a confirmation
of the sequence assignments. The amino acid sequences obtained are shown in Fig. 8.
Isolation of Nucleic Acid
Total RNA was extracted from Scenedesmus by the
following procedure. 35 g of frozen cell paste was ground with 80 ml of buffer G (8 M guanidine HCl, 20 mM EDTA,
20 mM MES, pH 7.0, and 50 mM -mercaptoethanol) in a PowerGen 125 tissue homogenizer (Fisher) for
60 s set on high. The homogenate was extracted with 150 ml of
phenol/chloroform/isoamyl alcohol (25:24:1) and then spun in a Sorvall
GSA rotor for 45 min at 8000 rpm (10,400 × g) at
25 °C. The supernatant was recovered and the RNA precipitated with
0.2 volumes of 1 M acetic acid and 0.7 volumes of ethanol
while at
20 °C, overnight. The RNA was pelleted by centrifuging in
a Sorvall GSA rotor at 16,300 × g for 15 min at
4 °C. The pellet was washed twice with 10 ml of 3 M
sodium acetate, pH 5.2, with a final rinse of 15 ml of 70% ethanol.
The pellet was resuspended in 4 ml of RNase-free water and stored at
70 °C until use. Poly(A) containing messenger RNA was recovered
from undiluted total RNA using the Poly(A)Tract system from Promega,
according to the manufacturer's instructions. The integrity of the RNA
was confirmed by electrophoresis in 1% Tris acetate agarose gel.
Total chromosomal DNA was recovered from Scenedesmus by the following procedure. About 500 mg of cells were harvested from the surface of agar plates and resuspended in 500 µl of TSE (5 mM Tris-HCl, pH 8.5, 50 mM NaCl, and 5 mM EDTA). The resuspended cells were frozen dropwise in liquid nitrogen and then ground while frozen by using a mortar and pestle. Ground cells were suspended in 1.4 ml of TSE, 40 µl of proteinase K (2.5 mg/ml), 100 µl of 20% SDS, and 100 µl of 20% Sarkosyl. The mixture was incubated at 65 °C for 2 h, then extracted with 2 ml of buffer-saturated phenol, and centrifuged for 15 min at 9400 × g in a Sorvall HS-4 rotor. The supernatant was extracted with 2 ml of chloroform and spun as above. Nucleic acids were precipitated from the extracted supernatant with 0.1 volume of 3 M sodium acetate and an equal volume of isopropyl alcohol. The precipitate was pelleted by spinning at 9400 × g for 20 min in the HS-4 rotor and then dried in a Speedvac (Savant) and resuspended in 900 µl of TE (10 mM Tris-HCl, pH 7.5, 1 mM EDTA) in microcentrifuge tubes. RNA was digested with 20 units of RNace-it (Stratagene). Starch was removed by adding 300 µl of 7.8 M ammonium acetate and centrifuging 30 min at 12,000 × g. The DNA was precipitated by adding 1.8 ml of isopropyl alcohol and centrifuging 30 min at 12,000 × g. The DNA was resuspended in 1 ml of TE. Typical concentrations were 400 µg/ml.
Cloning and Sequencing
Oligo(dT)-primed cDNA was prepared from
Scenedesmus poly(A) mRNA by using a SuperScript
preamplification system from Life Technologies, Inc. This cDNA was
used as template for a polymerase chain reaction primed with the
appropriate oligonucleotides. The amplification employed a
"touchdown" cycle sequence (33) with the annealing temperature
dropping by 2 °C every 3 cycles, from 60 to 50 °C, followed by 15 cycles at 47 °C. The reaction product was electrophoresed in a Tris
acetate low melting point agarose gel and excised from the gel. The gel
was melted at 70 °C and a 10-µl aliquot was used as template in an
identical repeat amplification reaction, except that the amplification
was followed by a 30-min incubation at 72 °C to enhance the 3
addition of single deoxyadenosines by Taq polymerase. This
second amplification reaction produced a concentrated band of DNA that
was excised from a low melt gel and ligated directly into a pGEM-T
vector (Promega, Madison, WI), according to the supplier's
instructions. E. coli XL1-Blue (Stratagene) cells were
transformed with the ligation products and plated on LB medium
containing ampicillin.
Clones containing inserts of the expected size were sequenced on an ABI
377 automated sequencer. The nucleotide sequences of the cloned
fragments were used to design exact gene-specific primers. The primers
were then used for the rapid amplification of cDNA ends (RACE) in
conjunction with a 5 RACE kit and a 3
RACE kit from Life
Technologies, Inc. and used according to the manufacturer's
instructions, except for the substitution of expand high fidelity
polymerase (Boehringer Mannheim) in place of Taq polymerase.
Reaction products of each were run on low melt agarose gels. Both bands
were excised. As the expand high fidelity polymerase generates
blunt-ended fragments, the following step was included to add single
deoxyadenosine tails. 20-µl aliquots of each band were incubated at
72 °C for 30 min in the presence of 10 mM Tris-HCl, pH
8.3, 50 mM KCl, 1.5 mM MgCl2, 0.33 mM dATP, and 0.5 units of Taq polymerase. The
tailed fragments were then ligated into a pGEM-T vector. E. coli
cells were transformed with the ligation products and selected as
above.
A minimum of four independent clones were sequenced (both strands) for
each of the 5 RACE and 3
RACE products of the LF-1 and wild-type
cDNAs. Clones from the 5
end overlapped clones from the 3
end by
440 bases. Sequencing was performed as above, and the data managed
using the Lasergene SeqMan program (DNASTAR Inc.).
HPLC of Synthetic Peptides
HPLC was run at 45 °C on a Vydac C-18 column (218TP54,
Sum, 4.6 mm inner diameter × 25 cm) plus a C-18 guard column
with a gradient run from 100% 0.1% trifluoroacetic acid in
H2O to 30% 0.1% trifluoroacetic acid in H2O,
70% 0.1% trifluoroacetic acid in acetonitrile as described in Fig.
10.
The D1 protease is associated with the thylakoid fraction as described under the "Experimental Procedures." The liberation of the enzyme upon treatment of the thylakoids with Triton X-100 is consistent with its localization within the thylakoid lumen where it has access to its substrate, the C terminus of the D1 polypeptide.
Hydroxylapatite chromatography (Table I) is the first major purification step following protease extraction and is able to accommodate large amounts of protein. It removes carotenoid and chlorophyll pigments as well as about 80% total protein. The fractions containing D1 protease elute very near a red cytochrome band upon washing with 100 mM K2HPO4/KH2PO4, pH 7.0, and 10% glycerol.
|
The protease is bound to the hydrophobic interaction column at 1.2 M (NH4)2SO4 and then eluted using a decreasing concentration (NH4)2SO4 salt gradient. The elution profile, shown in Fig. 4, shows the protease eluting at 85 min as 0.67 M (NH4)2SO4 enters the column.
MonoQ anion exchange chromatography (Fig. 5) provides the largest increase in specific activity (Table I), with the protease eluting at a point in the elution profile where 0.14 M NaCl is entering the column and where the background protein concentration is low.
Preparative isoelectric focusing shows the enzyme migrating with an isoelectric point of 5.0 ± 0.1. This value agrees fairly well with a calculated (43) isoelectric point of 5.34, based on the translated sequence of the mature D1 protease (see below).
Gel filtration chromatography (Fig. 6 and Table I) shows peak activity
appearing at about 92 min from the start of the run. A comparison with
the elution times of a collection of standard proteins, run under the
same conditions, gives an estimated molecular mass ranging from 36 to
42 kDa. This agrees favorably with a molecular mass of 42 ± 1 kDa
based on SDS-PAGE (Fig. 7) and a
calculated (43) mass of 40,578 Da, based on the translated sequence of mature Ctp-protease (see below). These results indicate clearly that
the protease is monomeric.
The yields of the various steps and their respective specific activities are listed in Table I.
Cloning and SequencingThe HPLC-purified tryptic peptides of the purified D1 protease were sequenced as under "Experimental Procedures" and were ordered by matching them to translated D1 protease genes from wheat3 and spinach (27). Degenerate oligonucleotide primers "A" and "B" (Fig. 8) based on these sequences were designed to prime regions of minimum degeneracy in the cDNA at sites corresponding to the peptide fragments shown in Fig. 8. The spacing of the primers predicted a reverse transcriptase-PCR product of about 770 bp.
Oligo(dT)-primed cDNA was prepared from Scenedesmus
poly(A) mRNA as described under "Experimental Procedures." This
cDNA was used as template for PCR using touchdown cycle sequence
and using as primers the oligonucleotides A and B (Fig. 8).
Electrophoresis of the reaction product produced a faint band of about
770 bp. This band was then used as template for a second round of a
repeat amplification reaction as described above. The 770-bp product was 3-extended with a single deoxyadenosine, ligated into a pGem-T vector (Promega, Madison, WI) and cloned and sequenced. The nucleotide sequence was then used to design gene-specific primers for RACE as
described above. The 5
RACE procedure produced an amplified DNA
product that was 1 kilobase pairs in length. The 3
RACE procedure yielded a product that was 1.4 kilobase pairs in length. These were
purified, 3
-tailed, and ligated into pGEM-T vectors.
Multiple independent clones were sequenced as a precaution against mutations introduced during the course of DNA amplification. We reasoned that a true mutation, present in LF-1, would appear in all LF-1 clones and in none of the wild type clones, whereas amplification mutants would appear randomly. A mutation rate of 1 error per 2000 bases sequenced was still observed despite the use of a "high fidelity" polymerase.
Once the nucleotide sequence difference between the D1 protease genes of LF-1 and wild type was determined by sequencing the RACE clones, the mutation was verified in the Scenedesmus genome by PCR amplification and sequencing of the homologous region. 2 µg each of chromosomal DNA from the wild type, LF-1, and the suppressor strain, LF-1-RVT-1, were used as template. A pair of gene-specific primers 507 bp apart, according to the cDNA sequence, was used to prime the reaction, which used the touchdown method described above. The reaction products were run on a standard agarose gel, and the predominant band, running at 1200 bp, was excised. The fact that the genomic PCR product was 700 bp larger than expected indicates the presence of one or more introns. The DNA was recovered using GeneClean (Bio 101, La Jolla, Ca) and sequenced as above using the same primers used for PCR.
Comparison of Amino Acid and Nucleotide SequencingThe 5 end
of the mRNA from wild type was determined by sequencing 5
RACE
clones. A total of 21 was sequenced, and the three longest showed a
consistent start point. The remaining clones were shorter and had
random start points, presumably the result of incomplete cDNA
synthesis. The first in-frame methionine was designated the start
codon.
Nucleotide sequencing of the wild type Scenedesmus cDNA predicts a protein of 464 amino acids. Of these the first 77 comprise a leader sequence as N-terminal amino acid sequencing of the mature protein indicated the first residue to be valine 78 (Fig. 8). A thylakoid transit sequence can be discerned with basic residues (Lys-39 and Arg-40), 38 and 37 residues, respectively, upstream from the mature N terminus, followed by a region of hydrophobic residues and terminating in a typical AXA lumenal processing site (34, 35). Upstream of the transit sequence is a region, enriched in serines and threonines, that is characteristic of a chloroplast signal sequence (36).
Nucleotide sequencing of the cDNA isolated from the LF-1 mutant
revealed a single base deletion in the glycine 387 codon that shifts
the reading frame, causing a translation stop after 2 amino acids (Fig.
9).
The point mutation was confirmed in genomic DNA by using PCR to directly sequence a 500-bp region of the LF-1 mutant and wild type genomes. In addition, the same region was sequenced from an LF-1 suppressor strain (LF-1-RVT-1, Ref. 31), which was shown to have a single base pair insertion 7 bases downstream of the LF-1 deletion. This insertion restores the proper reading frame and gives rise to three amino acid replacements with respect to wild type (Fig. 9).
Specificity of Proteolytic CleavageThe correspondence in vivo between the ability to express the full-length gene product and D1 processing activity demonstrates a clear cut role of the gene product in in vivo D1 processing. That this gene product is indeed the D1 C-terminal processing protease and not a cofactor in proteolytic processing is indicated by the demonstration of in vitro processing of D1. The use of an antibody in the ELISA assay that is directed against the mature C terminus would argue that processing occurs as expected at Ala-344. The specificity of proteolytic cleavage by the purified enzyme was further examined using a synthetic 19-mer peptide corresponding to the last 19 residues of the D1 polypeptide of Scenedesmus (NAHNFPLDLASVEAPSVNA). Shown in Fig. 10 is the HPLC chromatographic elution profile run as described under the "Experimental Procedures" of the 19-mer standard (NAHNFPLDLASVEAPSVNA) as well as the 9-mer (SVEAPSVNA) and 10-mer (NAHNFPLDLA) standards that are expected to result from D1 proteolytic cleavage of the 19-mer. Also shown is the 19-mer alone incubated for 4.25 h at room temperature with Scenedesmus D1 protease purified according to the complete procedure described above. The products are observed to migrate with the same mobility as the 9-mer and 10-mer standards indicating that cleavage by the enzyme occurs between Ala-10 and Ser-11 of the 19-mer, corresponding to Ala-344 and Ser-345, respectively, of the D1 polypeptide as observed in vivo.
Properties of the EnzymeThe molecular mass, isoelectric
point, and extinction coefficient of the mature Scenedesmus
enzyme (387 residues) were calculated using the Peptidesort program of
the Wisconsin Sequence Analysis Package (43). These are 40,577 Da and
5.34 and 21,740 M1 cm
1 (280 nm), respectively. These compare favorably with a measured molecular
mass of 40,635 ± 248 Da as determined by MALDI (accurate to
0.1%) and an experimental isoelectric point of 5.0 ± 0.2 as determined by isoelectric focusing. The measured mass indicates that
the enzyme is processed only at its N terminus.
Assuming the initial extraction of enzyme to be quantitative, the
amounts of enzyme recovered in the purification (Table I) imply a ratio
of enzyme to PSII reaction center to be on the order of 1/100-1/1000.
The t1/2 of in vivo processing of the D1
polypeptide in Scenedesmus by pulse-chase labeling was
estimated to be 1-2 min (13). A comparison of the two numbers gives an
in vivo turnover rate for the enzyme of between 1 and 10 s1.
The purified D1 protease was tested against a collection of classical proteinase inhibitors at concentrations that were 10 times the usual upper limits needed for inhibition in their respective classes. These included antipain (500 µg/ml, serine and cysteine proteases), 4-amidinophenylmethanesulfonyl fluoride (400 µg/ml, serine protease), aprotinin (500 µg/ml, serine protease), chymostatin (1 mg/ml, chymotrypsin), 3,4-dichloroisocoumarin (5 mM, serine protease), diisopropyl fluorophosphate (5 mM, serine protease), E64 (10 mg/ml, cysteine protease), EDTA (10 mM, metalloprotease), EGTA (10 mM, metalloprotease), iodoacetamide (10 mM, cysteine protease), leupeptin (5 µg/ml, serine and cysteine proteases), pepstatin (7 µg/ml, aspartate protease), o-phenanthroline (10 mM, metalloprotease), N-ethylmaleimide (10 mM, cysteine protease), phosphoramidon (3.3 mg/ml, metalloendopeptidase) phenylmethylsulfonyl fluoride (10 mM, serine protease). None of these reagents gave any appreciable inhibition of the D1 protease (data not shown), implying its membership in a new class of protease. These results are consistent with the observations of Bowyer and collaborators (25) and Satoh and collaborators (37) on the Scenedesmus and spinach proteases, respectively.
Sensitivity to Various SaltsExamination of the sensitivity of the enzyme to various ion additions to the normal assay medium (20 mM HEPES-KOH, pH 7.25, 20% glycerol) showed an approximate 4-fold rate enhancement by 5 mM MnCl2 or 5 mM FeSO4. These same salts showed 2.5- and 2-fold stimulation at 1 mM. There was a 2-3-fold stimulation by 1 and 5 mM MgSO4. CuSO4 and ZnSO4 gave rate enhancements of 4- and 2-fold, respectively, at 1 mM but a slight inhibition of rate compared with no additions at 5 mM each. There was practically no effect of EDTA or EGTA at 5 mM. While these effects are substantial, it is not clear whether these ions activate at the level of the enzyme or of the substrate or both. The substantial activation by Mn2+ may be of significance considering that pre-D1 processing precedes the assembly of the manganese cluster.
The LF-1 mutant strain of Scenedesmus was isolated by Dr. Norman Bishop following x-ray mutagenesis (20, 30). This mutant has been extensively studied by a number of groups and shown to be unable to process the precursor form of the D1 polypeptide or to assemble a functional manganese cluster (13, 20-22). Bowyer and collaborators (22) concluded that LF-1 lacked active protease by showing that while a cell extract from the wild type was able to render thylakoid membranes from the LF-1 mutant photoactivable for oxygen evolution, a similar extract from the LF-1 mutant was unable to do so. We have presented here a purification procedure that yields nearly homogeneous Scenedesmus protease. Nearly 50% protein was sequenced (Fig. 8), and the sequence was used to isolate the corresponding gene. A comparison of the gene sequence of the wild type Scenedesmus D1 protease gene to that of the LF-1 mutant provides an explanation for the loss in D1 processing activity. A deletion in LF-1 of a base pair (within codon 387 (Figs. 8 and 9)) produces a frameshift and a premature stop, resulting in the expression of a truncated translation product. In the photoautotrophic LF-1-RVT-1 suppressor strain that is once again able to process pre-D1, the insertion of a base 7 nucleotides downstream of the deletion restores in-frame translation, thus clearly linking pre-D1 processing activity to the present gene.
The correlation of in-frame translation of the present gene with the ability to process pre-D1 in vivo, the localization of the protease to the thylakoid lumen where the C terminus of pre-D1 is located (13, 29), and the specific in vitro cleavage by the enzyme at the pre-D1 processing site in PSII core complexes and in the pre-D1 mimic synthetic peptide all contribute to the conclusion that the enzyme isolated is indeed the D1 Ctp-protease. That the mutation in LF-1 completely inactivates processing of pre-D1 implies that the enzyme described here is the only D1 protease responsible for in vivo D1 C-terminal processing. It is also clear from the N-terminal sequence that once the enzyme is transported into the lumen, the transit peptide is removed at the carboxyl side of the characteristic AXA processing site of lumenally directed transit peptides. The close agreement between the measured mass of the isolated D1 protease (40,635 ± 248 Da) and the mass calculated from the translated gene sequence (40,577 Da) means that processing of the enzyme only occurs at the AXA N-terminal processing site. The presence of the protease in the thylakoid lumen (see also Refs. 27 and 28) is consistent with the localization in the lumen of its substrate, the C terminus of pre-D1 (29). The lumenal localization of the enzyme also implies that pre-polypeptide D1 is processed only after it is inserted into the membrane and folded such that the unprocessed C terminus extends into the lumen.
Many of the inhibitors that have proven effective against individual
classes of proteases show little propensity for inhibition in the case
of the D1 protease isolated from either spinach (37) or
Scenedesmus (25, this work), contributing to the idea
that this enzyme belongs to a new class of protease. Pakrasi
and collaborators (23) have pointed out the homology that exists
between Synechocystis ctpA and Escherichia coli
tail-specific protease (tsp (38), also called prc
(39)), responsible for C-terminal processing of penicillin-binding
protein. Like D1 protease, Tsp protease is resistant to the common
serine protease inhibitors, phenylmethylsulfonyl fluoride and
diisopropyl fluorophosphate (41). A comparison of the sequences of D1
proteases isolated from Scenedesmus as well as from
cyanobacteria and higher plants (Fig.
11, see also (27, 40)), a partial list
of which is included here, reveals very few conserved residues. A
clustering of conserved residues from 299 to 336 (PLVVLV to GKG, Fig.
11) is particularly marked and has been noted by Inagaki et
al. (27) as well. Keiler and Sauer (41) have inactivated enzyme
activity by introducing certain site-directed mutations into the
homologous regions of E. coli Tsp protease and have proposed
that a serine (homologous to D1 protease Ser-310 in Fig. 11 and Ser-372
in Fig. 8) and a lysine (homologous to D1 protease Lys-335 in Fig. 11
and Ser-397 in Fig. 8) are likely active site residues. If so, then D1
protease would join a family of enzymes that would include LexA
repressor, class A -lactamases, and type I signal peptidases (41)
where serine would be the attacking nucleophile and lysine rather than
histidine the coupled base. The location of these residues is
particularly significant as the stop codon that appears in the mutated
D1 protease gene of LF-1 lies within the active site region (codon 389 from start, Fig. 8; codon 327 from mature N terminus, Fig. 11) assuring the expression of inactive protease.
Given the elevated pKa of lysine in solution (10.8) and the low pH (4-5) of the thylakoid lumen, there would need to be a substantial lowering of its pKa for lysine to act as a proton acceptor in the active site. Such a pKa lowering can come either from the enzyme itself or from the enzyme-substrate complex. Consistent with the former is a concentration of residues with cationic side chains in the region of the putative active site (e.g. Lys-320, Lys-323, Arg-324, and Arg-331, numbering from the mature N terminus, Fig. 11). Nonetheless, the pH optimum of the isolated enzyme in the ELISA assay (Fig. 3, pH 6.3) is similar to what has been observed by others and higher than what is predicted for the pH of the thylakoid lumen. It is likely, therefore, that there are other factors in vivo that shift the pH dependence of the enzyme so that it is active in the physiological pH range.
The nucleotide sequence(s) reported in this paper has been submitted to the GenBankTM/EMBL Data Bank with accession number(s) U85200.
We are grateful to Dr. Norman Bishop for providing the Scenedesmus wild type, LF-1, and LF-1-RVT-1 strains. We also thank Dr. Xiao-Song Tang for helpful discussion, Barbara Larsen for MALDI mass spectrometry, Thomas Miller for N-terminal sequence data, Rand Schwartz for excellent technical assistance, Silvia Stack for nucleotide sequencing data, Winona Wagner for help with large scale algal growth, and James Metz for introducing us to Scenedesmus.