From the Department of Pediatrics, Division of Molecular Genetics and Naomi Berrie Diabetes Center, Columbia University College of Physicians and Surgeons, New York, New York.
Address correspondence and reprint requests to Streamson C. Chua, Jr., MD, PhD, Department of Pediatrics, Division of Molecular Genetics, Columbia University College of Physicians and Surgeons, Russ Berrie Medical Science Pavilion, 1150 St. Nicholas Ave., New York, NY 10032. E-mail: sc569{at}columbia.edu .
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ABSTRACT |
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INTRODUCTION |
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Animals with a null mutation in Lep (Lepob/ob mice) are obese, hyperphagic, cold intolerant, insulin resistant (and frequently glucose intolerant), have an abnormally regulated hypothalamic-pituitary-adrenal axis, and are infertile (1). Peripheral administration of recombinant leptin to ob/ob mice completely reverses the obesity by decreasing food intake and increasing energy expenditure (7). Additionally, peripheral leptin treatment in ob/ob mice restores glucose tolerance, cold tolerance, and fertility (7,8). The effects of leptin on feeding behavior, energy balance, and glucose homeostasis appear to be centrally mediated, as these actions of peripherally administered leptin can be produced with intracerebroventricular injections at doses too low to affect circulating leptin concentrations (1-3 µg) (9). Although central leptin administration appears sufficient to reverse the obesity/diabetes phenotype in ob/ob mice, several groups have reported effects of leptin in isolated peripheral tissues in vitro (e.g., pancreas [10], muscle [11], liver [12], and adipose tissue [13]). The relevance of these actions of leptin outside of the nervous system to the normal in vivo physiology of energy and glucose homeostasis are currently unclear.
The leptin receptor protein (LEPR) is a member of the class I cytokine receptor superfamily that activates the JAK/STAT (Janus kinase/signal transducer and activator of transcription) signaling pathway (14,15). Multiple splice variants of Lepr mRNA have been identified, each encoding an identical ligand binding domain, but differing by virtue of the presence or absence of a transmembrane domain or a complete cytosolic domain (14,16). Of the four "short" splice variants (LEPR-A, C, D, and E) identified, the LEPR-A isoform is the quantitatively dominant molecular species and is expressed in all tissues examined (17). All of the LEPR isoforms that possess a cytosolic domain (A, B, C, and D) also contain the same JAK binding motif encoded in coding exon 17. However, only the LEPR-B isoform contains a Box 3 motif for STAT activation in its terminal cytosolic domain (14,16,18). The LEPR-B isoform is expressed ubiquitously, but at levels much lower than the A isoform. An exception to this is the hypothalamus, where LEPR-B constitutes up to 35% of Lepr transcripts (17,19).
Consistent with its homology to the cytokine receptor family, LEPR-B is capable of dimerizing and activating STAT3 and STAT5 proteins in heterologous systems (19,20) Thus, the LEPR-B isoform is proposed to be the physiologically relevant signaling isoform in the regulation of energy balance. Consistent with this inference, db/db mice, which lack only functional LEPR-B, develop an obesity/diabetes syndrome apparently identical to ob/ob mice and are unresponsive to peripheral or central leptin administration (9). Furthermore, mice and rats possessing allelic mutations in the Lepr gene that affect all LEPR isoforms (db3J [21], dbPas [22], dbNCSU [23], fa [24], and fa-f [25]) exhibit the db/db obesity/diabetes phenotype. Studies in vitro have revealed LEPR-A signaling activities (e.g., immediate-early genes [26]) but the physiological relevance of this pathway to in vivo energy and glucose homeostasis is not clear.
As an initial step toward analyzing the function(s) of leptin receptor isoforms in vivo, we have created mice bearing a transgene expressing the B isoform of the leptin receptor under the control of the neuron-specific enolase (NSE) promoter (27). We find that the expression of this transgene (NSE-Rb) in db3J/db3J mice, otherwise null for all leptin receptor isoforms, partially rescues the obesity/diabetes and infertility phenotypes, while correcting the cold intolerance of these mutants. Quantitative analysis of the neuropeptides expressed by three hypothalamic neuronal populations indicates that the NSE-Rb transgene affects the expression of proopiomelanocortin (POMC), neuropeptide Y (NPY), and agouti gene-related protein (AGRP), whereas expression of melanin concentrating hormone (MCH) is unaffected by the transgene. We postulate that the partial correction of the obese/diabetes phenotype is due to the restoration of leptin sensitivity to POMC and AGRP/NPY hypothalamic neurons. We also postulate that the residual obesity and insulin resistance of NSE-Rb db3J/db3J mice may be due to the persistent abnormal activity of hypothalamic NPY/AGRP and MCH neurons. Furthermore, expression of NSE-Rb in animals lacking only LEPR-B (db/db mice) results in body weights similar to those seen in NSE-Rb db3J/db3J mice, suggesting that short LEPR isoforms play a limited role in body weight regulation. These experiments indicate the feasibility of using molecular genetic tools to dissect the roles of specific neuronal populations in energy balance, body weight regulation, and appetitive behavior.
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RESEARCH DESIGN AND METHODS |
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Production of transgenic mice. DNA was microinjected into fertilized C57BL/6JxCBA F2 oocytes. Surviving oocytes were transferred to the oviducts of pseudopregnant foster mothers according to previously described methods (30). These procedures were performed by the Herbert Irving Comprehensive Cancer Center Transgenic Mouse Facility at Columbia University. Sixteen progeny were obtained, two of which were positive for the transgene by PCR analysis of ear-clip DNA (see below; male #3 and male #12). The two male founders were mated with C57BL/6J.129-Awj db3J congenic females (see below). Both males transmitted the transgene to their progeny. The expression of the transgene was evaluated in progeny by reverse transcription (RT)-PCR analysis using two primer pairs: the 5' end was amplified using primers based on sequences after the NSE transcription start site and a sequence specific to LEPR-B, and the 3' end was amplified using primers based upon the SV40 polyA sequence and a LEPR-Bspecific sequence. The progeny of male #3 expressed full-length LEPR-B mRNA. The progeny of male #12, however, expressed a truncated LEPR-B mRNA consisting only of the 3' end. Thus, only line #3 was used for further analysis and line #12 was discontinued.
Line #3 progeny were backcrossed to C57BL/6J.129-AwJ/AwJ db3J/+ congenics to generate N3E and N4E (N3 and N4 equivalent, respectively) experimental animals. The B6 congenic line used (N10F4 or N10F5 C57BL/6J.129-AwJdb3J mice) carrying the db3J mutation was developed by this laboratory from 129/J-db3J animals provided by Dr. Ed Leiter (Jackson Labs). The db3J mutation was crossed onto white-bellied agouti C57BL/6J-AwJ mice (co-isogenic with C57BL/6J) to enable easy visual discrimination from black C57BL/6J mice harboring the db mutation (see below). To generate NSE-Rb db/db animals, transgenic progeny of initial matings (line #3) were initially crossed with FVB.C57BLKS/J-db congenic females (congenic FVB.BLKS-db animals were generated by this laboratory and were used in initial matings to increase the number of transgenic progeny). Progeny from this mating were backcrossed to C57BL/6J-m db congenic mice to generate N1 and N2 experimental animals. The B6 congenic line used (N10F4 or N10F5 C57BL/6J-m db mice) carrying the db mutation was developed by this lab using N8 C57BL/6J-m db/+ + breeders obtained from Jackson Labs. This is the stock in which the misty and diabetes mutations are maintained in the same phase. However, as our breeding progressed, we have observed numerous examples of recombination between misty and diabetes, i.e., obese animals that were not misty. Therefore, we have not specified the genotype at the misty locus for the experimental animals.
All animals used were maintained under barrier condition at 22°C with a 12h:12h light-dark cycle (0700-1900). Animals had free access to rodent food (Picolab Mouse Diet 20: 55% carbohydrate, 20% protein, 9% fat; PMI Nutrition International) and water unless specified. Pathogen testing is done on a quarterly basis, and all serologies have been negative to date.
Preparation and analysis of genomic DNA. Transgenic mice were identified using PCR analysis of genomic DNA isolated from ear clips or tail clips. Tissue was digested in a buffer of 1% SDS, 1 mmol/l EDTA, 10 mmol/l Tris, pH 8.0 with 100 µg/ml proteinase K at 65°C overnight, followed by phenol/chloroform extraction and DNA precipitation. Amplification with primers NSE-Ex1B (5'-CCACCGGCTGAGTCTGCAGT-3') and rGHINT-R (5'-TTGGCGCGCCGAGAGTCTAGAAAGAGAGACA-3') produced a 242-bp fragment if the transgene is present and no product if the transgene is absent. The genotype at Lepr was determined by PCR analysis of ear-clip DNA as follows: the 17-bp deletion of the Leprdb3J mutation was identified using the following primers:
Ex-11R: 5'-GTTCTTCAGTCACGCTTGA-3'Lepr-53: 5'-CATGAGGTATTCGATGCAAAG-3'
The Leprdb mutation was identified by an RsaI restriction site introduced by the mutagenic primer db-F1 and db-R (31):
db-F1: 5'-AGAACGGACACTCTTTGAAGTCTC-3'db-R: 5'-CATTCAAACCATAGT-TTAGGTTTGTGT-3'
Semiquantitative RT-PCR for LEPR and neuropeptide transcripts. Total
RNA was isolated from tissues extracted with guanidinium salts
(32). Two micrograms of total
RNA was reverse transcribed using MMLV Reverse Transcriptase (Life
Technologies) and an anchored oligo-dT primer adaptor (Not-PA, Promega) as
described by the manufacturer. Expression of the NSE-Rb transgene was
evaluated using a nested PCR strategy. Two microliters of cDNA (20 ng
equivalents of total RNA) was amplified with primers mObr-25
(5'-GATTTCACCACAACTTTCATTCTC-3') and Not-PA using the following
conditions: 94°C, 30 s; 55°C, 30 s; 72°C, 30 s for 20 cycles. One
microliter of this PCR reaction was amplified with primers Lepr-Rb1
(5'-CCTGTTCCACGCACAGTCAC-3') and Not-PA using the same PCR
conditions as above for 35 cycles. A 255-bp fragment was generated if the
NSE-Rb transcript was present. This protocol, however, did not amplify the
endogenous LEPR-B transcript. The integrity of cDNA was examined by PCR
amplification using a primer complementary to actin
(5'-CTGGAGAAGAGCTATGAGCTGCCT-3') and Not-PA, generating a 510-bp
fragment (ß-actin) and a 691-bp fragment
(sk-actin).
One to two micrograms of hypothalamic RNA was reverse transcribed with Superscript II (Life Technologies) with 200 ng of the Not primer-adaptor and 0.5 mmol/l dNTPs in a total volume of 20 µl. After incubation at 45°C for 60 min, the samples were diluted to 200 µl with sterile water and incubated at 65°C for 20 min to inactivate the reverse transcriptase. All samples being compared were reverse transcribed simultaneously to minimize differences in the efficiency of cDNA synthesis. To minimize variation due to sample handling, all samples to be compared were amplified on the same thermal cycler, and all amplification products for a given pair of primers were electrophoresed on the same gel. Amplification of LEPR-B cDNA was performed with isoform-specific primers for 40 cycles (94°, 55°, and 72° with 30 s at each temperature):
mObr-G: CCC ATC GAG AAA TAT CAGmLepr-60: GGC TCC AGA AGA AGA GGA CC
Amplification of actin cDNA was done for 26 or 28 cycles (same cycling parameters as for LEPR-B cDNA) with the following primers:
Actin-1: CTG GAG AAG AGC TAT GAG CTG CCTActin-3: CTC CTG CTT GCT GAT CCA CAT CTG
Amplification of neuropeptide cDNAs was done with the following primers:
AGRP AGRP-1: AGG GCA TCA GAA GGC CTG ACC AGG AGRP-2: CTT GAA GAA GCG GCA GTA GCA CGTMCH MCH-1: GAG TCC ACA CAG GAA AAG AG MCH-2: CAG CAG GTA TCA GAC TTG CC
NPY NPY-61: ATG CTA GGT AAC AAG CGA ATG GGG NPY-CPON: TGA AAT CAG TGT CTC AGG GCT GGA
POMC POMC-1: GTG CCT GGA GAG CAG CCA GT POMC-2: GAA GTT CCT CGG GGA CAG TC
The cycling parameters for three neuropeptide cDNAs (AGRP-32 cycles, NPY-30 cycles, and POMC-32 cycles) were 94° - 60° - 72°C for 30 s at each temperature plateau, whereas MCH cDNA was amplified for 26 cycles with an annealing temperature of 55°C. The optimal cycle number was determined from the db3J/+ cDNA pool to place the linear range of amplification for 20-fold dilutions of the cDNA samples. All of the primer pairs are designed to span at least one intron to distinguish between amplification products derived from genomic DNA and cDNA. All primer pairs were empirically shown not to amplify any products from genomic DNA using the specified conditions. Primers were based on mouse and rat cDNA sequences: ß-actin (33), AGRP (34), MCH (33), NPY (GenBank Accession # AF273768), and POMC (35). The rat MCH sequence was aligned to two mouse MCH-like expressed sequence tags for optimal homology to mouse MCH mRNA.
For quantitative analysis of LEPR-B transcripts, serial twofold dilutions
(6 for db3J/+ and db3J/db3J
and 12 dilutions for NSE-Rb db3J/db3J) were
amplified in duplicate with LEPR-B and actin primers. For quantitation of
neuropeptide cDNAs, the samples were diluted 1:20 with water, and 5 µl of
the diluted samples was used for amplification in duplicate in 25 µl
reactions. A standard curve was generated from serial twofold dilutions (8-10
dilutions in duplicate) of a pool of the cDNA samples from
db3J/+ animals. The procedure has been previously
described (23). The amplified
products were size fractionated on an agarose gel (2% agarose + 1%
low-melting-temperature agarose) containing ethidium bromide. DNA-bound
fluorescence was quantified with an 8-bit video camera using QuantOne software
(BioRad). The amount of amplified product is determined by the following
equation:
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Measurement of blood glucose, leptin, and insulin. Tail blood for glucose, insulin, and leptin measurements was collected from fed and/or 24-h fasted animals between 0800 and 1200 while they were lightly restrained. Glucose was measured using the glucose-oxidase method (Glucometer Elite; Bayer, Elkhart, IN). Serum insulin was quantified using a commercial radioimmunoassay kit with rat insulin as standard (Linco, St. Louis, MO). Serum leptin was quantified using a commercial enzyme-linked immunosorbent assay kit (Crystal Chem, Chicago).
Measurement of fat pad weights and BMI. Animals were killed by CO2 asphyxiation and bled by cardiac puncture for measurement of leptin and insulin. The naso-anal length (NAL) was measured and the BMI calculated as the body weight/NAL2 (g/cm2). The right inguinal, retroperitoneal, and perigonadal depots and the mesenteric depot were dissected and weighed. The total adipose depot weight of each animal was defined as the sum of ([right inguinal, retroperitoneal, and perigonadal depots] x 2) + (mesenteric depot).
Glucose tolerance test. Tail blood was collected from 15- to 20-week-old mice before and after 24 h of food deprivation for measurement of whole blood glucose concentrations. After 24-h food deprivation, glucose (1 mg/g0.75) was administered intraperitoneally, and tail blood (5 µl) was collected for glucose measurements (while mice were lightly restrained) before and 20, 40, 60, and 90 min after glucose administration. Doses were calculated to a power function of body weight to accurately reflect metabolic mass.
Cold tolerance test. Core (rectal) temperature of individually housed mice was measured using a thermocouple probe (IT-18, Physitemp) connected to a thermocouple thermometer (BAT-10, Physitemp) at 22°C ambient and at 0.5, 1, 1.5, and 2 h after being placed at 4°C ambient. Mice were manually restrained during probe insertion.
Measure of food intake. Daily pelleted mouse chow (Picolab Rodent Chow 5058) intake of individually housed mice was calculated from 24-h, 48-h, or 72-h intake measures. Food intake was expressed as g chow/day and g chow · (g body wt)-0.75 · day-1.
Statistical analysis. All values are expressed as means ± SE, unless otherwise indicated. Statistical differences among genotypes were assessed by a Kruskal-Wallis H-test followed by a Mann-Whitney U test where appropriate. A paired Student's t test was used to assess statistical differences between fed and fasted states. A one-tailed test with a P value <0.05 was considered significant.
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RESULTS |
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Nested RT-PCR analysis showed that, as expected, the transgene is expressed in all brain regions examined (hypothalamus, cortex, hindbrain, and cerebellum) (Fig. 2A and B). Low levels of NSE-Rb expression were seen in adrenals, white adipose tissue, and testis. Of note, there was no detectable LEPR-B mRNA from the transgene in the pancreas or in brown adipose tissue. Comparison of LEPR-B expression from the NSE-Rb transgene and the endogenous Lepr gene was performed by semiquantitative RT-PCR of hypothalamic RNA from mice of three genotypes: db3J/+, db3J/db3J, and NSE-Rb db3J/db3J. Regression analysis was performed on the amplification products from serial twofold dilutions of hypothalamic cDNA with correction for actin content. The analysis indicated that the NSE-Rb transgene is being expressed at 14-fold (relative to db3J/db3J) to 30-fold (relative to db3J/+) higher concentrations in the hypothalamus than is the endogenous Lepr gene (Fig. 2C). The large differences in transcript concentrations derived from the transgene and the endogenous gene account for the failure to amplify a fragment from the endogenous gene using the nested PCR approach that used an anchored oligo-dT down-stream primer. We were unable to amplify any fragments that contained the 17-bp deletion of the db3J mutation from db3J/db3J mice (data not shown), indicating that the amplified LEPR cDNA products from db3J/db3J tissues are not full-length LEPR transcripts.
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The NSE-Rb transgene was backcrossed three times (N4 equivalents, 93%
C57BL/6J) to two Leprdb congenic lines, C57BL/6J
AwJ/db3J and C57BL/6J m db, to
generate a more uniform genomic composition and to allow direct comparisons to
published literature using the C57BL/6J strain. The db3J
mutation is maintained on the co-isogenic B6-AwJ line to
allow visual discrimination between the two congenic lines (the B6-m
db line produces black mice whereas the
B6-AwJ/db3J line produces white-bellied agouti
mice). All experimental animals were typed for the presence/absence of the
transgene, which was maintained in the hemizygous state. All matings were
between a transgenic mouse and a nontransgenic mate.
The NSE-Rb transgene partially corrects the obesity and hyperphagia of
db3J/db3J mice. The NSE-Rb transgene
significantly ameliorated the obesity of
db3J/db3J mice, as evidenced by somatic growth
curves (Fig. 3A and
B) and adipose depot
weights (Table 1). Adult (24-27
weeks old) NSE-Rb db3J/db3J mice weighed 35-40%
less than db3J/db3J mice but were significantly
heavier than db3J/+ mice. The weight difference between
adult NSE-Rb db3J/db3J and
db3J/+ mice was more pronounced in females: female NSE-Rb
db3J/db3J mice were 40% heavier than
female db3J/+ mice, whereas male NSE-Rb
db3J/db3J mice were only 20% heavier than male
db3J/+ mice (Table
1). Similar genotype and sex differences in BMI were also observed
(Table 1). The absolute fat mass
in female mice was significantly different among genotypes with
db3J/db3J > NSE-Rb
db3J/db3J > db3J/+.
However, fat pad mass as a percentage of body weight in female NSE-Rb
db3J/db3J mice was not significantly different
from female db3J/db3J mice, and fat as a
percent of body weight in both of these groups was significantly higher than
in db3J/+ mice. In contrast, no significant difference in
fat pad mass, in absolute or relative terms, was observed between male NSE-Rb
db3J/db3J mice and lean
db3J/+ mice, and both of these groups had significantly
less depot fat than male db3J/db3J mice.
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Serum leptin concentrations in 24- to 27-week-old mice were highest in db3J/db3J mice, consistent with prior observations in Lepr-deficient animals (39) (Table 1). The differences in serum leptin between NSE-Rb db3J/db3J and db3J/+ mice were proportional to the differences in adipose depot weights, and the leptin/fat mass ratio was similar between these two genotypes. The leptin/fat mass ratio of male and female db3J/db3J mice was significantly higher than that in lean mice of the same sex. In females, the leptin/fat mass ratio of db3J/db3J mice was significantly higher than that of NSE-Rb db3J/db3J mice. However, this difference was not seen in male animals (Table 1). Twenty-four hours of fasting decreased plasma leptin in lean (db3J/+, +/+) mice, although it failed to do so in both db3J/db3J and NSE-Rb db3J/db3J mice (Table 2). Fasting for an additional 24 h did not decrease serum leptin concentrations of either db3J/db3J or NSE-Rb db3J/db3J mice (data not shown). Thus, the transgene failed to restore the deficit in fasting-mediated regulation of plasma leptin seen in db3J/db3J mice.
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The lower body weight and total fat pad mass of NSE-Rb db3J/db3J mice was associated with lower daily food intake (Table 3). The 24-h food intake of 11- to 12-week-old NSE-Rb db3J/db3J mice was not significantly different from the intake of db3J/+ mice, although there was a trend toward a higher intake in male NSE-Rb db3J/db3J mice (P = 0.08). No significant differences among groups were observed when food intake was expressed as a power function of body weight (body weight0.75), which is proportional to metabolic mass.
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The NSE-Rb transgene corrects the cold intolerance of db3J/db3J mice. Mice that lack leptin or LEPR are hypothermic and have a reduced thermogenic response to cold challenge, due primarily to decreased sympathetic stimulation of brown adipose tissue (40). When 16- to 20-week-old male db3J/db3J mice were placed at 4°C, there was a significant 7.4 ± 1.7°C decrease in their core temperature by 1 h as measured with a rectal probe (Fig. 4A). The basal core temperatures of wild-type (+/+), db3J/db3J, and NSE-Rb db3J/db3J male mice were not significantly different. Both the +/+ and NSE-Rb db3J/db3J male mice maintained their core temperature during 2 h at 4°C, with no significant difference from the basal core temperature in either genotype at any time point.
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The correction of the thermogenic defect by the transgene is attenuated in females (Fig. 4B). The db3J/db3J females have a slightly lower core temperature than the db3J/+ females. There is no difference in core temperatures between db3J/+ and NSE-Rb db3J/db3J females. When exposed to cold, the db3J/db3J females have a dramatic decrease in core temperature (6.2° over 40 min), whereas db3J/+ females show no alterations in core temperatures. The NSE-Rb db3J/db3J females show a small but significant drop in core temperature (1.5° over 90 min), which is significantly different from db3J/+ females.
The NSE-Rb transgene restores fertility in male db3J/db3J mice. Both Lep- and Lepr-deficient mice are infertile (1). To evaluate the effect of the NSE-Rb transgene on fertility in Lepr-null mice, we mated NSE-Rb db3J/db3J mice (four males and three females) to lean (db3J/+) mice. All of the NSE-Rb db3J/db3J males sired at least two litters of normal size. However, none of the NSE-Rb db3J/db3J females produced litters. It was not determined if the females were cycling or were impregnated but failed to bring any fetuses to term.
The NSE-Rb transgene partially corrects the glucose intolerance of db3J/db3J mice. Another hallmark of Lep- and Lepr-deficient mice is insulin resistance and a strain-dependent glucose intolerance (1). The NSE-Rb transgene fully corrected the postprandial hyperglycemia of both male and female db3J/db3J mice (Table 2). There was, however, only a partial correction of the hyperinsulinemia. It is possible that the hyperinsulinemia in NSE-Rb db3J/db3J mice is due to their persistent excess adiposity. The glucose tolerance curves of male NSE-Rb db3J/db3J and lean mice were similar (Fig. 5A), although there was a trend for the NSE-Rb db3J/db3J mice to have higher glucose values at 40 min after glucose administration. The glucose tolerance curves of female NSE-Rb db3J/db3J mice were intermediate between those of db3J/db3J and db3J/+ or +/+ mice, indicating a persistent but attenuated glucose intolerance (Fig. 5B).
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Effects of NSE-Rb on expression of hypothalamic POMC, NPY, AGRP, and MCH. To specify the neuronal substrates that mediate the various effects of the NSE-Rb transgene, we performed quantitative analysis (by semi-quantitative RT-PCR and in situ hybridization) of the hypothalamic expression of four neuropeptide genes (Fig. 6A-D that are regulated by leptin and abnormally expressed in LEPR-deficient rodents: POMC, AGRP, NPY, and MCH. POMC transcripts (Fig. 6A) are normalized (increased twofold over db3J/db3J male mice) by the NSE-Rb transgene in male db3J/db3J transgenics, whereas female db3J/db3J transgenics had a large increase (fivefold) in POMC mRNA concentrations over lean and db3J/db3J females. Although we did not observe any differences in POMC mRNA between the db3J/+ and db3J/db3J genotypes, the observation of a significant increase of POMC mRNA in the transgenic females indicates the bestowal of leptin sensitivity of POMC neurons by the NSE-Rb transgene in both male and female db3J/db3J mice. Leptin-receptor deficiency increased Agrp expression (Fig. 6C), whereas AGRP transcripts were reduced by the transgene but not normalized to the amounts observed in db3J/+ animals in both male and female NSE-Rb db3J/db3J mice. We also found a reduction, but not full normalization, of NPY mRNA (Fig. 6B) in male db3J/db3J mice due to the transgene by in situ hybridization, although we were unable to observe a transgene effect by RT-PCR analysis (data not shown). Contrary to the NSE-Rb transgene's effects on arcuate nucleus neurons, there was no difference in MCH mRNA (Fig. 6D) concentrations between db3J/db3J and NSE-Rb db3J/db3J mice of both sexes, although lean db3J/+ mice of both sexes had significantly lower MCH mRNA concentrations than the db3J mutant mice (transgenic and nontransgenic). Therefore, the partial corrections in the obesity/diabetes phenotype that are observed in the NSE-Rb db3J/db3J mouse may be due to the restoration of leptin sensitivity to arcuate nucleus neurons expressing POMC/cocaine- and amphetamine-regulated transcript (CART) and AGRP/NPY, whereas the residual deficiencies could be due to dysregulation of MCH neurons in the lateral hypothalamus and some AGRP/NPY neurons in the arcuate nucleus.
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Presence of other LEPR isoforms on effects of the NSE-Rb transgene. It is possible that the failure of the NSE-Rb transgene to correct completely the obesity in LEPR-null (db3J/db3J) mice is due to the absence of other LEPR isoforms (e.g., LEPR-Ra, Rc, Rd, or Re). To explore this possibility, we evaluated the effect of the NSE-Rb transgene on the obesity of db/db mice that are deficient in only the B isoform of LEPR. Similar to observations in db3J/db3J mice, the presence of the NSE-Rb transgene did not fully correct the obesity phenotype of 16- to 18-week-old male db/db mice. The body weights of db/db (n = 5), NSE-Rb db/db (n = 4), and db/+ or +/+ (n = 3) mice were 70 ± 2, 53 ± 1, and 43 ± 2 g, respectively, and the adipose depot masses were 13 ± 0.5, 6.7 ± 0.6, and 5.8 ± 0.1 g, respectively. Because NSE-Rb db/db mice possess the full complement of short LEPR isoforms, the lack of a full correction of obesity in NSE-Rb db3J/db3J mice cannot be explained by the absence of these short LEPR isoforms. The possibility that the short isoforms may subtly modify the phenotype of NSE-Rb db/db animals relative to NSE-Rb db3J/db3J animals cannot, however, be excluded.
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DISCUSSION |
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The control of feeding behavior and energy expenditure by circulating leptin appears to be mediated primarily by LEPR-B signaling within the hypothalamus. The demonstrations that LEPR-B expression is highest in the hypothalamus (19), that peripheral and central leptin injections produce similar effects on feeding and energy expenditure in Lep-null mice (7,8,9), that db/db mice and Lepr-null mice have an apparently identical obesity/diabetes phenotype (1), and that peripheral leptin injection activates STAT3 in hypothalamic neurons but not in peripheral tissue (41) are consistent with this view. Within the hypothalamus, leptin seems to act by modulating the expression, release, and actions of several orexigenic and anorexigenic neuropeptides (42).
The NSE-Rb db3J/db3J transgenic mice express the LEPR-B mRNA at high levels throughout the brain and at much lower levels in adrenals, testis, and white adipose tissue. The NSE-Rb db/db transgenic mice have the same pattern of LEPR-B expression but possess the full complement of short LEPR isoforms in all tissues. The demonstration that the body weights of the NSE-Rb db3J/db3J and NSE-Rb db/db mice are similar suggests that the shorter LEPR isoforms are of limited importance in body weight regulation. The failure to achieve a full correction of the obesity phenotype of Lepr-null mice may be attributed to one or more of the following potential factors: 1) absence of the LEPR-B transgene in critical hypothalamic neurons due to mosaic expression; 2) failure of the transgene to enable production of the appropriate number of leptin receptors in relevant neurons; and 3) absence of LEPR-B transgene expression in critical peripheral tissue(s).
Both CNS and direct peripheral actions of leptin have been proposed to mediate the hormone's effects on glucose homeostasis. Because the NSE-Rb transgene is not expressed in the pancreas or in skeletal muscle, the effects of circulating leptin on glucose metabolism in NSE-Rb db3J/db3J mice must be mediated by LEPR-Bmediated signaling events in the CNS or white adipose tissue. Although the endogenous NSE gene (Eno2) is expressed in all peripheral and central neurons, the DNA fragment used in constructing the NSE-Rb transgene does not fully replicate the pattern of expression of the natural Eno2 gene. Moreover, integration site effects have important consequences for transgene expression, emphasizing the necessity of characterizing each transgene integration site independently. The increased skeletal muscle glucose uptake in response to intracerebroventricular leptin administration suggests that leptin's effects on skeletal muscle are mediated primarily through the CNS (43). Although direct actions of leptin on adipocytes are possible, it is likely that circulating leptin affects the adipose tissue glucose metabolism of NSE-Rb db3J/db3J mice via CNS-related mechanisms, because the transgene reduces the ratio of circulating leptin to fat pad mass (Table 1) in NSE-Rb db3J/db3J mice. Reports demonstrating no direct effects of leptin on glucose transport and metabolism in adipocytes (44,45,46), or modest effects on glucose metabolism using supraphysiological concentrations of leptin (47), are consistent with this model.
NSE-Rb db3J/db3J mice lack LEPR-B expression, and thus LEPR-mediated signaling, in brown adipose tissue. The complete restoration of cold tolerance in NSE-Rb db3J/db3J male mice is consistent with restoration of LEPR-mediated efferent sympathetic nervous traffic in the LEPR-deficient rodents (48,49). Furthermore, because no LEPR isoforms are expressed in brown adipose tissue of NSE-Rb db3J/db3J mice (Fig. 2A-B,2C), the restoration of cold tolerance in these mice indicates that reported direct effects of leptin on glucose and lipid metabolism in brown adipose tissue in vitro (47) can be replaced by sympathetic activation mediated by leptin-responsive neurons. Similarly, sympathetic activation with a sympathetic agonist or a cold environment can circumvent the thermogenic defect of leptin deficiency (50,51).
The NSE-Rb transgene restored fertility in male db3J/db3J mice. It is possible that the restoration of fertility in male NSE-Rb db3J/db3J mice is due to expression of the NSE-Rb transgene in testis (Fig. 2A-B,2C). Recent work, however, demonstrates that plasma leptin enters the testes in a nonsaturable manner and that LEPR is not expressed in Leydig or Sertoli cells (52), which raises questions regarding the relevance of LEPR as a transporter or as a signaling mechanism in this tissue and suggests that the effect of the NSE-Rb transgene on fertility in male LEPR-null mice is due to the restoration of central LEPR-B signaling. The failure of the transgene to restore fertility in female LEPR-null mice may be due to the persistent adiposity seen in these mice or to the failure to correct completely the defects in the hypothalamic-pituitary-gonadal axis, and not to a requirement for LEPR-B signaling in ovarian tissue. These inferences are supported by the facts that ovaries transplanted from db/db mice to +/+ mice function normally (53) and that mice made obese by high-fat feeding fail to cycle normally (54). Additionally, preliminary data show that NSE-Rb db/db female mice are not fertile whereas NSE-Rb db/db males are, indicating that the lack of short LEPR isoforms in the ovaries of NSE-Rb db3J/db3J mice is not responsible for the failure to restore fertility. The sex differences that the NSE-Rb transgene produces are intriguing. Although we have shown that the transgene did not integrate into the X chromosome (male hemizygotes produce male and female transgenic progeny), it is possible that the transgene integrated at a site that confers sex-specific modulation of transgene expression. There were no data that indicated that the NSE promoter has sex-specific effects on transgene expression.
The quantitative analysis of neuropeptide gene expression in the
hypothalamus suggests a critical role for POMC and AGRP/NPY
(55) arcuate nucleus neurons
in the obesity/diabetes syndrome of leptin-receptor deficiency
(42). Although these are the
neuropeptide genes whose transcript concentrations were measured, it is likely
that the entire set of neurotransmitter activities of these two neuronal
populations is affected by the NSE-Rb transgene, such as CART in POMC neurons
(56,57,58),
because leptin hyperpolarizes neurons
(59), thereby inhibiting
neuronal activity and synaptic transmission. It is remarkable that several
aspects of LEPR deficiency, such as glucose tolerance and fertility in males,
can be corrected by near-normalization of leptin sensitivity in POMC and
AGRP/NPY neurons. It should be noted that NPY deficiency does not correct
glucose intolerance in leptin-deficient mice
(60), whereas overexpression
of Agouti (61) and AGRP
(34) does not produce overt
diabetes, suggesting that the activity of hypothalamic POMC neurons is
important to the maintenance of normoglycemia. In support of this supposition
is the observation that mice lacking the melanocortin receptor 4
(MC4R)the receptor for -melanocyte stimulating hormone (a
peptide processed from the POMC preprotein) and AGRPdevelop
hyperglycemia and are also infertile
(62). However, an intact
hypothalamus is necessary for the development of hyperglycemia in
LEPR-deficient rodents (in diabetes-susceptible strains) because ventromedial
hypothalamic lesions, either chemically or electrolytically induced, prevent
the development of diabetes without affecting the degree of obesity
(63). Ventromedial
hypothalamic lesions also ablate the arcuate nucleus, removing both POMC and
AGRP/NPY neuronal populations. Because we have not controlled for adiposity
between transgenic and nontransgenic LEPR-deficient mice in our study, it
remains a formal possibility that the diminished adiposity in NSE-Rb mice may
be sufficient to account for improved glycemic control. Based on a comparative
survey of the current literature cited previously, we believe that it is
likely that the combined actions of at least two neuronal populations in the
arcuate nucleus, including POMC neurons and AGRP/NPY neurons, are important
for regulating glucose homeostasis.
The persistent adiposity, insulin resistance, and female infertility of NSE-Rb LEPR-deficient mice may be ascribed to the partial (for AGRP/NPY neurons) or complete (for MCH neurons) leptin insensitivity of a subset of hypothalamic neurons. The lack of fasting-induced suppression of circulating leptin by the NSE-Rb transgene suggests that LEPR may be a potential regulator of leptin secretion. Although our data are compatible with the possibility of peripheral actions of leptin/leptin receptor contributing to the obesity/diabetes syndrome, a direct test of this hypothesis is required by evaluation of the phenotype of mice expressing LEPR-B in adipocytes only. In addition, we are performing further studies where higher levels of LEPR-B transgene expression, i.e., in the homozygous state, may affect adiposity in lean and genetically obese mice.
In summary, we have demonstrated that expression of LEPR-B predominantly in the brain of mice otherwise null for all LEPR isoforms affects all fundamental aspects of the obesity/diabetes syndrome, as the NSE-Rb transgene partially rescues the obesity/diabetes phenotype, restores fertility in male animals, and fully corrects the impaired thermoregulatory thermogenesis in males. Future experiments in transgenic mice in which expression of LEPR-B is restricted to specific hypothalamic neurons (e.g., POMC-or AGRP/NPY-expressing neurons) or peripheral tissues (e.g., adipose tissue) will help to define the minimum molecular and neuronal phenotypes required for mediation of leptin's behavioral and metabolic effects.
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ACKNOWLEDGMENTS |
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The authors would like to acknowledge the contributions of Norichika Okada and James Koutras in the construction of the NSE-Rb transgene; Joel Elmquist and Charlotte Lee for in situ hybridization analysis of the NSE-Rb transgene; and Eric Corp for leptin binding visualization.
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FOOTNOTES |
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AGRP, agouti gene-related protein; CNS, central nervous system; JAK, Janus kinase; LEPR, leptin receptor protein; MCH, melanin concentrating hormone; NAL, naso-anal length; NPY, neuropeptide Y; NSE, neuron-specific enolase; PCR, polymerase chain reaction; POMC, proopiomelanocortin; RT, reverse transcription; STAT, signal transducer and activator of transcription; SV40, simian virus 40.
Received for publication July 20, 2000 and accepted in revised form October 11, 2000
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REFERENCES |
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