(Received for publication, November 15, 1996, and in revised form, December 30, 1996)
From the III. Department of Zoology-Developmental Biology, University of Göttingen, Humboldtallee 34A, 37073 Göttingen, Germany
A main structure of the mammalian sperm tail is a
structure known as the outer dense fibers whose molecular composition
as well as their function are still mostly unknown. We report here the
isolation and characterization of new cDNAs (odf2) that
identifies a highly variable gene locus encoding outer dense fiber
proteins. Transcription of odf2 is restricted to testis and
more specifically to round spermatids. Transcription starts in step 6 spermatids, which coincides with transcription of the major outer dense
fiber protein gene odf1 (Burmester, S., and
Hoyer-Fender, S. (1996) Mol. Reprod. Dev. 45, 10-20) and
with the formation of the sperm tail. Affinity-purified anti-Odf2
antibodies identified isolated outer dense fibers immunocytochemically
and detected at least three protein bands in the molecular mass range
of 65,000 to 70,000 Da in total Odf protein preparations. Presence of
several protein bands correlates with the presence of several
transcripts and the isolation of slightly different cDNA clones,
whereas Southern blot hybridization does not indicate the presence of
multiple genes. Computer analyses of the structure of the encoded Odf2 protein revealed an overall -helical structure with two regions identical to the dimerization region of the leucine zipper motif.
A main component of the mammalian sperm tail is a structure composed of nine fibers, the accessory or outer dense fibers (Odf).1 These fibers surround the axoneme on its outer side in parallel to the tubuli doublets in the middle and principle piece of the sperm tail. Anteriorly, the Odf make close contact with the paracentriolar connecting piece and extend posteriorly for varying lengths into the principle piece. At the annulus, which marks the border between the middle piece and the principle piece of the sperm tail, two of the nine Odf terminate abruptly and are replaced by the two longitudinal columns of the fibrous sheath, a structural component peculiar to mammalian spermatozoa (2). The possible function of these Odf may be to maintain the passive elastic structure and elastic recoil of the sperm tail and/or to protect it against shearing forces during epididymal transport (3). Accessory fibers have been found in many groups within the animal kingdom, including insects (4).
In mammalian sperm, the outer dense fibers consist of several proteins in the molecular mass range from about 11 kDa to about 87 kDa (4-9). Biochemical analyses have shown that in rat spermatozoa the Odf are composed of six major polypeptides in one study (7) or of at least 14 polypeptides in another (8). The main Odf protein of rat spermatozoa with a molecular mass of about 30 kDa and a high cysteine and proline content is also the main zinc-binding protein of the sperm tail (10). Recently, we have identified and characterized the gene encoding this major Odf protein (odf1) from rat, man, and mouse (1, 11-14).
To gain an understanding of the molecular composition and the function of Odf in sperm motility and the biochemical properties of the individual outer dense fiber proteins, it was our objective to isolate and characterize additional genes that encode Odf proteins or Odf-associated proteins. Here we describe the isolation and characterization of nearly identical and up to now unknown cDNA clones (odf2) that encode Odf proteins of rat spermatozoa. The cDNA clones were isolated from a rat testis cDNA library by initial screening with an antiserum directed against total Odf proteins of rat sperm and subsequent hybridization screenings with the isolated cDNA. odf2 is expressed specifically in testis, with transcript sizes of 2.2, 2.0, and 1.6 kb. By Northern blot hybridization to RNA of rat testes of different developmental stages and by in situ hybridization to rat testis sections, postmeiotic transcription was clearly demonstrated. Transcription starts in step 6 spermatids of tubular stage VI. Affinity-purified anti-Odf2 antibodies identified isolated Odf immunocytologically and detected at least three protein bands on Western blots of total Odf proteins.
Outer dense fibers were isolated from epididymal rat spermatozoa as described previously (7). An antiserum against total Odf proteins was raised in rabbits by Eurogentec.
Isolation of cDNA Clones and Sequence AnalysesScreening of the Lambda ZAP II rat testis cDNA library (Stratagene) was performed by standard methods (15, 16). DNA sequences were determined (17, 18) using Sequenase 2.0 (Amersham Corp.).
RNA Preparation and Northern Blot HybridizationTotal RNA was prepared by guanidinium HCl lysis (19). Poly(A) RNA was isolated from total RNA with oligo(dT)15-Dynabeads (Dynal). RNA was denatured, electrophoresed on 1% agarose gels, and transferred to Hybond-N (Amersham) as described previously (20, 21). Northern blot hybridization was performed according to Schäfer et al. (22). RNA probes were generated by in vitro transcription and labeled simultaneously by incorporation of [32P]UTP.
Southern BlotsGenomic DNA was isolated by standard methods (23), digested with restriction endonucleases, separated on 1% (w/v) agarose gels in TPE (60 mM Tris, 50 mM NaH2PO4, 2 mM EDTA, pH 8.0), blotted to Hybond-N (Amersham) (24), and hybridized in 5 × SSC, 5 × Denhardt's solution, 0.5% SDS, 100 µg/ml denatured salmon sperm DNA at 65 °C. Posthybridization washing was performed twice in 2 × SSC and once in 1 × SSC, 0.1% SDS and in 0.1 × SSC, 0.1% SDS at hybridization temperature. DNA probes were labeled with [32P]dATP by the random hexanucleotide primer method (25).
5Isolation and cloning of the 5 end of odf2
cDNA was performed with the 5
RACE system, Version 2.0 (Life
Technologies, Inc.) according to the instruction manual. The PCR
products obtained were cloned into pGEM-T (Promega) or pCR-Script
(Stratagene) and sequenced on both DNA strands.
The conditions for polymerase chain reaction are as follows: initial denaturation for 5 min at 94 °C followed by 35 cycles of 0.5-min denaturation at 94 °C, annealing at 52 °C for 1.5 min, and elongation at 72 °C for 2.5 min, with a final step at 72 °C for 10 min.
Western BlottingOdf proteins were separated by SDS-polyacrylamide gel electrophoresis (28) and transferred to Hybond-C (Amersham) (29). The membrane was blocked in 5% powdered milk in TBST (10 mM Tris-HCl, pH 7.6, 150 mM NaCl, 0.05% Tween 20), and incubated with the anti-Odf antiserum, diluted 1:50 in blocking solution. Bound antibodies were detected via binding of anti-rabbit-IgG antibodies linked to horseradish peroxidase (Sigma) and chemiluminescence (ECL-Western blotting (Amersham) and Renaissance Western blot chemiluminescence reagent (DuPont NEN)).
Expression of odf2 Fusion Protein and Affinity Purification of Antibodiesodf2 cDNA was cloned into pGEX-3X
(Pharmacia Biotech Inc.). Odf2 protein, fused to glutathione
S-transferase, was expressed by induction with 1 mM isopropyl-1-thio--D-galactopyranoside at
37 °C, and proteins were separated on SDS-polyacrylamide gels (28).
The antiserum was first preabsorbed with immobilized total Escherichia coli proteins including glutathione
S-transferase. The preabsorbed antiserum was then incubated
with total E. coli proteins containing the Odf2 protein
fused to glutathione S-transferase. Elution of bound
antibodies was performed as described previously (30). Binding
specificity of the eluted antibodies was tested on Western blots
containing total Odf proteins as described previously.
Rat sperm outer dense fibers were air-dried onto slides and fixed in acetone. Antibody incubation was performed with the affinity-purified anti-Odf2 antibody, diluted 1:400. Detection was performed using the Vectastain Elite ABC-Kit (Vector) and subsequent color reaction with diaminobenzidine. Controls were performed without the first antibody, but incubation with the second antibody and color reaction with diaminobenzidine.
In Situ HybridizationPreparation of tissues and in situ hybridization was essentially performed as described elsewhere (1).
Outer dense fibers were isolated from rat spermatozoa (7). Light microscopic examination of the preparation revealed the contamination with sperm heads. The solubilized proteins were used to raise antibodies, and the antiserum was fractionated according to the molecular mass of their antigens. The antibody fraction directed against Odf proteins with molecular masses greater than 45 kDa was used to screen a rat testis cDNA library. This initial screening yielded five clones that cross-hybridize.
The DNA sequence of the largest clone consists of 1365 bp without the
poly(A) tail. Nineteen bases in front of the 3 end of the cDNA,
the presumably polyadenylation signal AATAAA is present. It is obvious
from Northern blot hybridizations (see Fig. 4), that the isolated clone
is not a full-length cDNA clone. Screening of the rat testis
cDNA library with anti-Odf antibodies and with the isolated
cDNA clone itself yielded no full-length clone. Instead, several
smaller clones as well as one clone of about 1.6 kb were obtained. All
clones sequenced revealed that they are mostly but not completely
identical. The most remarkable difference between these clones is an
insertion of 69 nucleotides that does not interrupt the reading frame
and therefore represents 23 additional amino acids. The missing 5
end
of the complete odf2 cDNA was obtained by reverse
transcription of rat testis mRNA and amplification of the 5
region. After a first round of PCR, two weak product bands of about 1 kb and 800 bp were present (not shown). These two PCR products were
cloned and sequenced on both DNA strands. The complete nucleotide
sequence of the largest odf2 cDNA as well as its derived
amino acid sequence is shown in Fig. 1. This
odf2 cDNA consists of 2,182 bp without the poly(A) tail.
Between nucleotides 949 and 950 the 69-bp insertion was found in
another cDNA clone. The largest open reading frame of the 2,182-bp
odf2 cDNA consists of 1,773 bp from base 305 to base
2,077. This open reading frame encodes a protein of 591 amino acids
with a deduced molecular mass of 68,671 Da and an estimated isoelectric
point of 6.04.
The sequence of the smaller 5 RACE product (Fig. 2) is
in part identical to the described odf2 sequence. The 3
end
of this cDNA is identical to the odf2 sequence, whereas
the 5
end shows no sequence similarities. This 5
RACE product may be
therefore representative for another odf2 cDNA with a
different 5
end. The amino acid sequence of the putative protein may
be therefore identical to the amino acid sequence of Odf2 with the
exception of the first 40 amino acids and two amino acid exchanges at
positions 99 and 115. The putative protein of this sequence has an
estimated molecular mass of 64,486 Da.
The odf2 cDNA Sequence Is Highly Variable
It is obvious
from the sequencing of a lot of cDNA clones isolated by antibody
and hybridization screenings and the sequencing of the 5 RACE products
that several slightly different odf2 cDNAs exist. First,
between nucleotides 949 and 950 of the odf2 sequence shown
in Fig. 1, a 69-bp insertion was found in another cDNA clone. Amplification of the region flanking this insertion demonstrates the
presence of both sequences (with and without the insertion) in rat
testis cDNA synthesized from total and poly(A) RNA (not shown).
Second, the existence of nearly identical odf2 cDNAs
with different 5
ends was verified by amplification of the individual 5
regions from rat testis cDNAs (Fig. 3). In Fig.
3, lanes a and b, amplification of the 5
end of
odf2 was performed with a primer specific for the 5
sequence shown in Fig. 1 (oligo 86: CACCTTGTATCCATCCCC, nucleotides
2-19) and a primer specific for nucleotides 1,351-1,369 (oligo 82:
CTCGGCATACTCCTCACTC). In lanes c and d
amplification of the 5
end of another cDNA (GenBankTM
accession no. X95272[GenBank], see "Discussion") is shown, performed with a
primer specific for this cDNA (oligo 87: CACGAGGAAGCGGGGAGG; see
"Discussion") and the oligo 82, and in lanes e and
f amplification of the 5
end of the cDNA shown in Fig.
2 was performed with a specific primer (oligo 88: AGACTGTATGCCTGGAGG;
nucleotides 6-23 in Fig. 2) and oligo 82. The results revealed that
all these sequences are present in rat testis cDNA synthesized from
poly(A) RNA (Fig. 3, lanes a, c, and
e) as well as in rat testis cDNA synthesized from total
RNA (Fig. 3, lanes b, d, and f), and
are therefore not artificial. These three different 5
ends are also
present in transcripts with and without the 69-bp insertion (not
shown).
Three Testis-specific Transcripts Hybridize to odf2
The
odf2 gene is specifically transcribed in testis (Fig.
4). In RNA isolated from testis of adult rats, at least
two hybridization signals could be obtained (Fig. 4B,
lane a). The strongest signal may be composed of two RNA
species at about 2 kb with slightly different lengths (see Fig.
5), whereas the weaker signal is composed of RNA smaller
than 2 kb in length. In somatic rat tissues odf2 is not
transcribed (Fig. 4B, lanes b-f). Hybridization
of odf2 to RNA isolated from rat heart, liver, muscle,
kidney, and spleen (Fig. 4B, lanes b-f), and
also to rat brain and lungs (data not shown) yielded no hybridization
signal. It is obvious from the gel, after staining with ethidium
bromide, that the amount of total RNA from somatic tissues used for
Northern blot hybridization is greater or at least the same (Fig.
4A, lanes b-f) as that of the testicular RNA
(Fig. 4A, lane a).
Digestion of rat testis RNA with RNase H and subsequent Northern blot hybridization to odf2 cRNA confirmed the existence of three different odf2 transcripts (not shown). The lengths of the undigested odf2 transcripts are about 2.2, 2.0, and 1.6 kb, whereas the RNase H-digested transcripts are about 2.0, 1.8, and 1.4 kb. The poly(A) tails have been estimated to be between 120 and 180 bp in length.
Spermatid-specific Expression of odf2odf2
transcripts could first be detected in testis RNA of 30-day-old rats
(Fig. 5B, lane c), and their amount increases as spermatogenesis proceeds (Fig. 5B, lanes d and
e). Increasing amounts of odf2 transcripts could
be detected in RNA isolated from testis of 40-day-old rats (Fig.
5B, lane d) and adult rats that are older than 50 days (Fig. 5B, lane e). In testes of 10- and
20-day-old rats, no odf2 transcription occurs (Fig.
5B, lanes a and b). The amount of
total RNA in each slot is shown after staining with ethidium bromide
and demonstrates that in lanes c to e nearly the
same quantities were used, whereas in lanes a and
b greater amounts of total RNA were loaded onto the gel (Fig. 5A). The absence of odf2 transcripts in
testes of rats younger than 30 days pointed to haploid transcription of
odf2. In testis of 30-day-old rats, spermiogenesis has just
started, and the germ cells have reached the stage of late round to
elongating spermatids (31). In situ hybridization to rat
testis sections confirmed the haploid transcription of odf2
(Fig. 6). In adult rat testis sections, odf2
transcripts could be clearly demonstrated in the cytoplasm of haploid
round spermatids of tubular stages VII/VIII and in the cytoplasm of
elongating spermatids of subsequent stages (Fig. 6A),
whereas control hybridization to labeled odf2 sense RNA
yielded no signals (Fig. 6B). Transcription starts in step 6 spermatids (not shown) of tubules of stage VI of the cycle of the
seminiferous epithelium. In these tubules a slight staining could be
demonstrated in the cell layer in the middle of the tubule, in which
the haploid round spermatids are located. The identification of the
stages of the seminiferous epithelium was performed after staining with
periodic acid-Schiff (not shown) following the definitions of the
stages given by Leblond and Clermont (32). In situ
hybridization to testis sections of 30-day-old rats confirmed the
results obtained by Northern blot hybridization. odf2
transcripts were detected in the cells at the lumen of the tubules that
are late round spermatids or early elongating spermatids (not
shown).
Proteins of the Outer Dense Fibers Are Encoded by odf2 cDNA
Antibodies specific to epitopes encoded by the largest
odf2 cDNA were affinity-purified from the antiserum
directed against total Odf proteins. After incubation of an immunoblot
containing total Odf proteins with the affinity-purified antibodies,
several proteins could be detected (Fig. 7). The two
main proteins are in the molecular mass range of more than 66,000 Da
(Fig. 7B). These two proteins are present in a much greater
amount than that protein with a molecular mass of about 65,000 Da,
which is also intensively stained with the antibodies. At least three
other protein bands are also detected by the affinity-purified
antibodies (Fig. 7B), whereas the major outer dense fiber
protein Odf1, with a molecular mass of about 30 kDa, did not
cross-react with the anti-Odf2 antibodies.
The identity of the proteins that were detected by the anti-Odf2
antibodies as outer dense fiber proteins was demonstrated immunocytologically. Incubation of isolated outer dense fibers of rat
sperm with the anti-Odf2 antibodies and staining with diaminobenzidine identified the outer dense fibers (Fig. 8A),
whereas no staining was obtained in identical control experiments
without the anti-Odf2 antibodies. (Fig. 8B).
odf2 at the Genomic Level
Since all results obtained indicate
the presence of several transcripts and several proteins, we performed
Southern blot hybridizations to investigate the number of
odf2 genes. Rat genomic DNA was digested with restriction
enzymes, electrophoretically separated, blotted, and hybridized to
odf2 cDNA (Fig. 9). All restriction
digests revealed only two or three bands at most. For BamHI,
HindIII, and SacI one and for PstI two
recognition sites are present in odf2 cDNA. Southern
blot hybridizations therefore do not indicate the presence of multiple
odf2 genes.
A remarkable feature of male germ cell differentiation is the formation of the sperm tail. The most prominent sperm tail structures are the outer dense fibers, whose composition and function are almost unknown. To characterize their protein constituents and to study their significance in sperm tail formation and function, we started to isolate cDNA clones encoding Odf proteins by an immunological approach. The isolated cDNA hybridizes to three transcripts exclusively in total RNA of rat testis, but not in RNA of somatic tissues, as was expected if it encodes a sperm tail-specific protein. The three testis-specific transcripts do not correspond to one transcript species with different poly(A) tail lengths, since no reduction in the number of RNA bands was found after digestion of poly(A) tails with RNase H. The transcripts without their poly(A) tails are about 2.0, 1.8, and 1.4 kb in length and might encode proteins of at least 70,000, 65,000, and 50,000 Da, respectively. Affinity-purified anti-Odf2 antibodies detect at least three proteins in total outer dense fiber protein preparations on Western blots. The antibodies react very strongly with two proteins in the molecular mass range of more than 66,000 Da, and with a third protein of approximately 65,000 Da. The lengths of the transcripts and the molecular masses of the proteins are calculated according to their electrophoretic migration as compared with molecular mass standards. This may explain the differences between calculated molecular masses of encoded proteins and the molecular masses of proteins reacting with the anti-Odf2 antibodies as obtained from denaturing polyacrylamide gels. But it can not be excluded that other features such as posttranslational modifications may also contribute to the differences in sizes.
Although no cDNA clone encoding a full-length transcript could be
isolated, the missing 5 end, and therefore the complete cDNA
sequence, was obtained by 5
RACE. Sequencing of many cDNA clones
and of the 5
RACE products and PCR amplification of parts of the
cDNA performed with different primer pairs reveal that several
nearly identical odf2 transcripts exist. These transcripts may be translated into proteins with similar amino acid sequences. The
protein bands in the total Odf protein preparation, which react only
weakly with the anti-Odf2 antibodies, may be proteins that share only
epitopes with the Odf2 proteins, or perhaps they are those Odf2
proteins present in minor quantities or modified to different amounts.
The apparent sequence variation of odf2 was found in all
experiments performed with probes from different individuals and is
therefore consistent across the population. Amplification of the RNA
variants by sequence-specific reverse transcription-PCR (Fig. 3) shows
that the most prominent odf2 transcript corresponds to the
largest transcript (Fig. 1), whereas the lowest transcript level was
found for the X95272 sequence. This is in agreement with the amount of
transcripts detected on Northern blots.
In a data base search, no identical sequence could be found but a
sequence of 2,203 bp that was deposited under accession no.
X95272[GenBank].2 This sequence is nearly fully identical to the
sequence of odf2, besides three nucleotide exchanges in the
3 region and greater differences in the 5
region. The sequence X95272[GenBank]
includes the 69-bp insertion found also in one of our cDNA clones.
This 69-bp insertion does not interrupt the reading frame and encodes therefore for additional 23 amino acids. The greatest difference in
sequence between odf2 and X95272[GenBank] is found in the 5
region.
Nevertheless, cDNAs with the 5
region specific for X95272 could be
detected in rat testis cDNAs (Fig. 3, lanes c and
d). The translation initiation codon of the largest
odf2 cDNA is present at position 305 and is surrounded
by the sequence GCGGAATGA that resembles the consensus sequence for
initiation of translation by eukaryotic ribosomes CCAGCCATGG (33) only
at positions
3 and
4. The open reading frame encodes a putative
protein of about 68 kDa that may represent one protein of more than 66 kDa detected in Western blots. The translation initiation codon of the
putative protein encoded by the cDNA with the smaller 5
RACE
product (Fig. 2) is found at position 63 and is surrounded by the
sequence GGACAATGT. This sequence resembles the consensus sequence for
the initiation of translation by eukaryotic ribosomes only at positions
2 and
3. Nevertheless, the putative protein has a molecular mass of about 65 kDa and may therefore represent the 65-kDa protein detected in
Western blots.
Analysis of the protein structure with the program "Protean" (DNA*,
Inc.) revealed an overall -helical structure of the complete Odf2
protein, that is in agreement with a protein component of fibrillar
structures. In the C-terminal region of the derived Odf2 protein, at
amino acid positions 392-413 and 530-551 (Fig. 1), two regions
identical to the dimerization region of the leucine zipper motif are
found. The leucine zipper motif may function in dimerization of Odf
proteins to generate longitudinal protein complexes of the outer dense
fibers.
The results obtained by Southern blot hybridization do not point to multiple odf2 genes. Although this cannot be totally excluded at the moment, these slightly different transcripts may be generated by alternative splicing. We are now working on the isolation and characterization of the gene(s).
Testis-specific and postmeiotic transcription of odf2 is clearly demonstrated, as is expected, if the gene encodes a protein important in spermatid differentiation. Transcription of odf2 starts in step 6 round spermatids with only minor transcript amounts. The start of transcription of odf2 corresponds to that of odf1, which encodes the major outer dense fiber protein (1). Even though the beginning of translation of odf2 has not been investigated, it may be similar to that of odf1, i.e. the start of translation in step 6 or 7 round spermatids. The beginning of transcription of both Odf genes corresponds to the most active period of Odf formation. Formation of Odf takes place during the acrosome phase, i.e. step 8 round spermatids to step 14 elongated spermatids, and early maturation phase, i.e. steps 15-17 elongated spermatids (34).
That odf2 indeed encodes an outer dense fiber protein was clearly demonstrated by immunocytochemical staining of isolated Odf. The isolated gene will now be used in isolation and characterization of odf2-related genes in other species to investigate the composition of Odf and to study the formation of the sperm tail. Moreover, odf2 is the second gene isolated encoding a structural component of sperm tail outer dense fibers. It should be very interesting to compare the regulation of expression of the two Odf protein genes, odf1 and odf2, and to investigate the cooperation of these proteins in formation and function of the sperm tail. Further experiments are currently under way.
The nucleotide sequence(s) reported in this paper has been submitted to the GenBankTM/EMBL Data Bank with accession number(s) U62821[GenBank].
We thank Ingeborg Streichhan for the photographic work.