(Received for publication, October 5, 1995)
From the
Parathyroid hormone-related protein (PTHrP) is produced by the pancreatic islet. It also has receptors on islet cells, suggesting that it may serve a paracrine or autocrine role within the islet. We have developed transgenic mice, which overexpress PTHrP in the islet through the use of the rat insulin II promoter (RIP). Glucose homeostasis in these mice is markedly abnormal; RIP-PTHrP mice are hypoglycemic in the post-prandial and fasting states and display inappropriate hyperinsulinemia. At the end of a 24-hour fast, blood glucose values are 49 mg/dl in RIP-PTHrP mice, as compared to 77 mg/dl in normal littermates; insulin concentrations at this time are 6.3 and 3.9 ng/ml, respectively. Islet perifusion studies failed to demonstrate abnormalities in insulin secretion. In contrast, quantitative islet histomorphometry demonstrates that the total islet number and total islet mass are 2-fold higher in RIP-PTHrP mice than in their normal littermates.
PTHrP very likely plays a normal physiologic role within the pancreatic islet. This role is most likely paracrine or autocrine. PTHrP appears to regulate insulin secretion either directly or indirectly, through developmental or growth effects on islet mass. PTHrP may have a role as an agent that enhances islet mass and/or enhances insulin secretion.
Parathyroid hormone-related protein (PTHrP) ()was
initially discovered in 1987 through its causative role in the most
common of the hypercalcemic paraneoplastic syndromes, humoral
hypercalcemia of malignancy(1, 2, 3) . It is
now widely appreciated that PTHrP is the product of a gene, which is
expressed not only in a broad spectrum of human and animal cancers, but
in almost every normal human and rodent tissue in which its expression
has been sought(3, 4, 6) . Oversecretion of
PTHrP into the systemic circulation by cancers (including carcinomas of
the pancreatic islet; (7) -9) leads to hypercalcemia in a
classical endocrine fashion through binding of PTHrP to parathyroid
hormone receptors in bone and
kidney(1, 2, 3, 4, 5, 6, 10) .
In contrast, there is growing consensus that the normal physiologic
roles of PTHrP are most often paracrine or
autocrine(1, 2, 3, 4, 5, 6) ,
or perhaps even ``intracrine'' as suggested by Kaiser,
Karaplis, and colleagues(11, 12) . The study of the
normal physiologic roles of PTHrP is in its infancy. These roles have
been reviewed recently (3, 4, 5, 6, 13) and appear
to include: 1) regulation of transepithelial calcium fluxes in the
nephron, in the breast, in the placenta, and in the distal oviduct or
shell gland of the hen; 2) regulation of uterine, vascular,
gastrointestinal, and urinary bladder smooth muscle tone; 3) regulation
of growth and differentiation in a broad variety of cell types and
organs including the keratinocyte, the chondrocyte, the osteoblast, the
cells of the proximal nephron, the breast, and many others. Importantly
in the current context, PTHrP is a key developmental factor. This is
apparent from the fact that in each of the transgenic mouse models of
PTHrP overexpression or of disruption of the PTHrP gene or its
receptor, dramatic developmental abnormalities occur: targeted
overexpression of PTHrP in the breast leads to striking mammary
ductular hypoplasia(14) , and overexpression of PTHrP in the
epidermal keratinocyte leads to failure of hair follicle
development(15) . Disruption of the PTHrP gene or its receptor
leads to severe and lethal skeletal developmental
abnormalities(16, 17) .
One of the tissues that
produces PTHrP under normal circumstances is the pancreatic islet.
Drucker, Goltzman, and colleagues have shown that PTHrP can be
identified in normal rat and human pancreatic islets; that PTHrP
colocalizes immunohistochemically with insulin, glucagon, somatostatin,
and pancreatic polypeptide in ,
,
, and PP cells within
the islet; and that mRNA encoding PTHrP is present in isolated rat
pancreatic islets(7) . PTHrP is also produced by islet cell
adenomas and carcinomas(7, 8, 9) . We have
confirmed that PTHrP is present immunohistochemically in the rat islet (18) and, as shown below, the mouse islet. We have shown that
cultured rat insulinoma cells of the line m5F display cytosolic calcium
responses to doses of PTHrP within the physiologic range, and that
these responses are mediated by receptors distinct from the classical
PTH receptor(18) . The observations: (a) that PTHrP is
normally produced in the pancreatic
cell, (b) that
pancreatic
cells contain receptors for PTHrP, and (c)
that under all normal circumstances studied to date, PTHrP plays local
paracrine or autocrine roles, together suggested that PTHrP could play
a normal regulatory or developmental role within the pancreatic islet.
In order to begin to define a possible normal physiologic role for PTHrP in the pancreatic islet, we have prepared two lines of transgenic mice in which PTHrP has been targeted to, and overexpressed in, the pancreatic islet using the rat insulin II promoter (RIP). These RIP-PTHrP mice display a syndrome that includes islet cell hyperplasia, hyperinsulinemia, and hypoglycemia.
Using these procedures, 26 founder generation mice were obtained from seven mothers. Of these 26 animals, seven were transgenic. Three markedly dwarfed founders containing the highest copy number of the transgene died shortly after birth, and two others were determined to be mosaics in that they failed to transmit the transgene to their progeny. Two true-breeding lines were generated from the two remaining founders, animals 1799 and 1807. These were outbred onto a Sencar background. The studies described herein were performed on animals derived from the 1799 and 1807 lines. The two lines were maintained separately, but because of their similar biochemical phenotypes, data from the two lines have been pooled except where indicated below. All of the studies described in this manuscript were performed on animals between the ages of 5 and 12 weeks, unless specifically indicated. All procedures were approved by the Yale University Animal Care and Use Committee and the West Haven VA Medical Center Animal Studies Committee.
Northern blotting of pituitary RNA was performed as described in the legend to Fig. 11using a mouse growth hormone cDNA probe, generously provided by Dr. Daniel Linzer at the University of Chicago, and a mouse proopiomelanocortin probe, generously provided by Dr. Richard Mains at Johns Hopkins University.
Figure 11: Panel A, expression of murine growth hormone (mGH) and murine proopiomelanocortin (mPOMC) mRNA in the pituitary of normal littermates (N) and transgenic animals (T). Five µg of pituitary total RNA prepared from pituitaries pooled from five animals was loaded in each lane. This blot was prepared from animals of the 1807 line, but indistinguishable results were found in the 1799 line as well. Panel B, circulating insulin-like growth factor 1 concentrations in normal and transgenic animals. See text for details.
Figure 5: Whole blood glucose (upper three panels) and plasma insulin (lower three panels) concentrations in non-fasting mice, after an 8-h fast, and after a 24-h fast. NL indicates normal littermates, and TG indicates RIP-PTHrP mice. Note that the insulin RIA employed for the non-fasting and the 24-h time points was the Zawalich insulin RIA(24) , while that used for the 8 h time point was the Linco insulin RIA as discussed under ``Materials and Methods'' and ``Results.'' The results indicate that glucose and insulin concentrations progressively and appropriately decline with fasting in the normal mice, whereas the RIP-PTHrP mice are hypoglycemic relative to their littermates at all time points studied, are inappropriately hyperinsulinemic at all time points, and have non-suppressible plasma insulin concentrations even in the face of marked hypoglycemia. The hyperinsulinemia is documented using two different insulin RIAs.
Plasma insulin-like growth factor 1 was measured by radioimmunoassay as described previously(27) .
Figure 8:
Perifusion of isolated islets derived from
RIP-PTHrP mice and their normal littermates. Perifusion was performed
as described under ``Materials and Methods'' on isolated
islets with either low glucose (G = 2.75
mM or 50 mg/dl glucose) or high glucose (G
= 20 mM or 360 mg/dl glucose) for the times
indicated. As indicated in the key on the right, large
closed circles represent the results of four perifusions of islet
from four normal animals, small closed circles the results of
four perifusions of islets from four RIP-PTHrP mice of the 1799 line,
and squares, four perifusions of the islets from four
RIP-PTHrP mice of the 1807 line. The diamonds are the mean of
all the transgenic data, and thus represent the results of eight
perifusions of islets isolated from eight
mice.
Figure 1: Appearance of the RIP-PTHrP mouse at 8 weeks of life (left) as compared to an age-matched normal littermate (right). Note that the RIP-PTHrP mouse is normally proportioned and healthy appearing. The size discrepancy first becomes apparent at 2-3 weeks of age and persists throughout life.
Figure 2: RNase protection analysis of total RNA prepared from pancreas from normal mice (N) and transgenic (T) RIP-PTHrP mice. The panel on the left shows a 24-h exposure, and the panel on the right shows the same gel exposed for 72 h. Note that the level of pancreatic expression of the human transgene (hPTHrP) is dramatic at the 24-h time point when the endogenous murine mRNA (mPTHrP) is invisible, and that the endogenous mRNA only becomes visible after 72 h of exposure. A mouse cyclophilin probe serves as an internal control.
Figure 3: Extra-islet expression of the RIP-PTHrP transgene. Total RNA (100 µg) prepared from the tissues shown in the figure, both from normal littermates (N) and transgenic animals (T), was analyzed using RNase protection analysis. As can be seen, low levels of transgene expression, as detected using the hPTHrP probe, were observed in the stomach (Sto), intestine (Int), liver (Liv), heart (Hrt), lung (Lng), whole brain (Brn), skin (Skn), and kidney (Kid). In general, mRNA expression was comparable to endogenous mRNA as detected using the mPTHrP probe. mCyclo indicates mouse cyclophilin. Gastric expression of the endogenous PTHrP gene is higher than in any other organ. These samples were obtained from animals with full stomachs; gastric distention has been reported to increase PTHrP expression (reviewed in (13) ).
In order to confirm that the transgenic animals overexpress the PTHrP at the peptide level, immunohistochemistry using two region-specific anti-PTHrP antisera was performed. As can be seen in Fig. 4, overexpression at the protein level is easily apparent. PTHrP appears to be expressed in essentially all of the cells of the islet using both PTHrP antisera. By rough estimate, PTHrP expression would appear to be 3-10 times higher in the RIP-PTHrP islet than in the normal islet.
Figure 4:
Immunohistochemical staining for PTHrP.
Immunohistochemistry for amino-terminal PTHrP (left two
panels) and mid-region PTHrP (right two panels) in normal
mouse pancreas (upper two panels) and RIP-PTHrP transgenic
mouse pancreas (middle two panels). Normal and transgenic
pancreas sections were processed identically on adjacent portions of
the same slide as described under ``Materials and Methods.''
The bottom panel shows staining of a RIP-PTHrP section with
the mid-region antibody following preincubation of the antibody with
10M PTHrP(37-74). Identical loss of
staining was obtained when the amino-terminal antibody was preincubated
with excess PTHrP(1-36) (not shown). The results indicate that
PTHrP, both amino-terminal and mid-region epitopes, is present in the
islets of the RIP-PTHrP mouse in substantially greater than normal
amounts. Although colocalization studies using antibodies directed
against insulin, somatostatin, glucagon, and pancreatic polypeptide
were not performed, the pattern of staining is consistent with
expression of the transgene in
-cells and perhaps
-,
-,
and PP cells as well.
Since the level of expression of the transgene was high, and since the pancreatic islet is a secretory cell with direct access to the circulation, it was important to determine whether systemic oversecretion of PTHrP occurred. Serum calcium concentrations were normal in both lines of RIP-PTHrP mice (mean ± S.E. = 9.4 ± 0.1 versus 9.3 ± 0.2 mg/dl, normal versus RIP-PTHrP, respectively, n = 10 animals in each group, p = N.S.), and circulating PTHrP concentrations as determined using an immunoradiometric assay for PTHrP(1-74) with a sensitivity of 4 pM in the mouse (25, 26) were undetectable in both lines of RIP-PTHrP mice. While appropriate samples of portal plasma could not be obtained from these miniature aminals, it is worth noting that an elevation in the portal concentration of PTHrP has not been excluded.
As can be seen in the three lower panels of Fig. 5, plasma insulin values were measured on the same samples from the RIP-PTHrP mice and their normal littermates. Surprisingly, in the non-fasting state, and after 8 h of fasting, plasma insulin values were slightly (but not significantly) higher in the RIP-PTHrP mice than in their normal littermates. Given the relative hypoglycemia in the RIP-PTHrP mice in the post-prandial and 8-h fasted states, one would have expected the plasma insulin values to have been lower in the RIP-PTHrP mice than in controls at these two time points. Further, the plasma insulin/glucose ratios were higher in the RIP-PTHrP mice than in their normal littermates at both of these time points; in the non-fasting state, the plasma insulin/glucose ratios (± S.E.) were 0.08 ± 0.01 versus 0.05 ± 0.01 (p = 0.08) in the RIP-PTHrP animals versus the normal littermates; corresponding values after 8 h of fasting were 0.23 ± 0.03 versus 0.14 ± 0.02 (p = 0.001).
After 24 h of fasting, insulin values were markedly higher in the RIP-PTHrP animals than in their normal littermates, and at this time point, the difference was highly significant in statistical terms (p = 0.002). Interestingly, the plasma insulin values after 24 h of fasting were no different than the corresponding values post-prandially (Fig. 5), indicating that plasma insulin is not suppressible by fasting hypoglycemia in the RIP-PTHrP mouse. Finally, in order to be certain that inappropriate hyperinsulinemia was present, plasma insulin concentrations were determined in two different laboratories using two different plasma insulin immunoassays as described under ``Materials and Methods;'' the values shown for the non-fasting and 24-h time points were performed in one assay (the Zawalich assay) and the 8-h fasting values in another (the Linco assay).
Levels of steady-state insulin mRNA were determined using RNase protection analysis of pancreatic total RNA. As shown in Fig. 6a, steady state insulin mRNA levels were 2-3-fold higher in the RIP-PTHrP mice as compared to their normal littermates. This overexpression of insulin was confirmed at the protein level by measuring insulin in pancreatic extracts by radioimmunoassay. As can be seen in Fig. 6b, RIP-PTHrP mice contained more than twice as much insulin as those of their normal littermates.
Figure 6: Pancreatic insulin mRNA and insulin content. Panel A shows steady-state insulin mRNA levels as assessed using RNase protection analysis of total pancreatic RNA from normal littermates (N) and from RIP-PTHrP transgenic (T) animals from lines 1799 and 1807. The probes used were a mouse insulin and a mouse cyclophilin cRNA as indicated in the Fig. and described in detail under ``Materials and Methods.'' Panel B shows the insulin content of normal and transgenic pancreas acid-urea extracts prepared and assayed as described under ``Materials and Methods.'' Note that both pancreatic insulin mRNA and insulin protein are 2-3-fold higher in the RIP-PTHrP pancreata than in those of their normal littermates.
Immunohistochemistry using insulin, glucagon, and somatostatin antisera is shown in Fig. 7. The distribution of insulin-, glucagon-, and somatostatin-containing cells in the RIP-PTHrP islet appears to be normal. No distributional or quantitative differences were observed for any of these three islet peptides between the RIP-PTHrP animals and their littermates.
Figure 7: Immunohistochemical staining for insulin, glucagon and somatostatin in paraffin sections of RIP-PTHrP pancreas. Staining for insulin (upper left), glucagon (lower left), and somatostatin (upper right) appear normal in the RIP-PTHrP islet, and are indistinguishable from staining patterns and intensities for the same three peptides in sections of pancreas of normal littermates (data not shown). The bottom right panel is a section for which the primary antibody was omitted, demonstrating the specificity of the staining.
Figure 9: Hematoxylin and eosin staining of representative sections of pancreas from normal mice (panel A) and RIP-PTHrP mice (panel B). Note that the RIP-PTHrP appear to have more than the normal number of islets, and that the islets appear to display a normal size distribution.
Figure 10: Quantitative islet histomorphometry of normal (NL) and RIP-PTHrP transgenic (TG) pancreas. The upper panel shows the volume of pancreatic islets as a function of arbitrary total pancreatic volume units. The lower panel displays the number of islets per square millimeter of total pancreatic area. Although not directly measured, it can be extrapolated from these findings that the mean volume or area of individual islets in normal and transgenic animals is comparable.
These studies demonstrate that PTHrP overexpression in the
pancreatic cells of transgenic mice leads to a syndrome of
hypoglycemia resulting from hyperinsulinemia. Taken together with the
observations that PTHrP is normally produced in pancreatic
cells (7, 8, 18) , and is capable in doses that are
well within the physiologic range (10
to
10
M) of eliciting cytosolic calcium
responses in a cultured
cell line(18) , these findings
suggest that PTHrP may play a normal paracrine, autocrine or perhaps
``intracrine'' (11, 12) physiologic role
within the pancreatic islet, and that this role directly or indirectly
may involve the regulation, biosynthesis or secretion of insulin.
A
primary question regards the mechanisms responsible for
hyperinsulinemia in the RIP-PTHrP mouse. It is in theory possible that
hyperinsulinemia and hypoglycemia result from islet-specific effects of
the promoter or to random insertional events relating to the location
of the transgene in the murine genome. The RIP promoter used in these
studies has been used extensively in the creation of other transgenic
mouse models. In two models of RIP promoter-targeted transgenic mice,
one involving yeast hexokinase (31) and the other involving
vasoactive intestinal polypeptide(32) , hypoglycemia and
hyperinsulinemia did occur. In these cases, there were sound
physiologic reasons for the occurrence of hypoglycemia. The other
RIP-transgenic models, e.g. the RIP-Tag
mouse(19, 20) , the RIP-G
mouse(33) , the RIP-TNF-
mouse(34) , and the
RIP-MHC-II mouse(35) , do not develop hypoglycemia, but more
typically develop glucose intolerance or frank diabetes. Since most RIP
transgenic models do not develop hypoglycemia, and since the
hypoglycemia and hyperinsulinemia were observed in two independent
lines of RIP-PTHrP mice, it is unlikely that random insertional
mutagenesis or islet-specific effects of the RIP promoter can explain
the findings. Rather, the results would appear to be a specific
consequence of PTHrP overexpression in the pancreatic islet.
Hyperinsulinemia was accompanied by increases in pancreatic insulin peptide and mRNA content. No qualitative or quantitative abnormalities in glucagon or somatostatin immunohistochemistry could be detected.
Hyperinsulinemia could result in the RIP-PTHrP mouse from
abnormalities in individual islet cells and/or within individual
islets. These defects could include abnormalities in cell glucose
sensing, inappropriate rates of insulin biosynthesis, a failure of the
normal regulation of insulin secretory mechanisms within the
cell
or a combination of the above. In order to test these possibilities,
perifusion experiments were performed using islets isolated from
RIP-PTHrP transgenic animals and their normal littermates. When
compared in this way, individual transgenic islets apperared to sense
glucose and secrete insulin appropriately. Insulin secretion was normal
in response to 0, 2.75, 10, and 20 mM glucose perifusion.
These findings support the interpretation that there are no intrinsic
abnormalities in the RIP-PTHrP islet or in individual RIP-PTHrP
cells, but rather that the hyperinsulinemia and hypoglycemia might
result instead from the observed increase in islet cell mass.
Two observations made during the preliminary characterization of the animals suggested that an increase in islet cell mass was present in the RIP-PTHrP mice. First, in the course of islet isolation for the perifusion studies, islets appeared to be of normal size but were more abundant and therefore easier to harvest from the RIP-PTHrP mice than from those of their normal littermates. Second, in initial histologic study of the pancreata from the RIP-PTHrP mice, it appeared that islets were more abundant than in their littermates. In order to examine this posibility in a formal manner, multiple histologic sections were prepared from pancreata from multiple RIP-PTHrP and control animals and these were subjected in a blinded fashion to quantitative islet histomorphometry. The quantitative histomorphometric findings confirmed our initial subjective impression; the RIP-PTHrP mice had approximately twice as many pancreatic islets per unit area of exocrine pancreas as did their littermates; and the aggregate islet area or volume in the RIP-PTHrP mouse was approximately 2-fold higher in the RIP-PTHrP mice than their littermates. By extrapolation, the average islet size would be normal in the RIP-PTHrP mouse.
These observations raise two
questions. The first question is, ``Given that the RIP-PTHrP mice
are smaller than their littermates, do the islet histomorphometric
findings represent an appropriately normal islet mass in otherwise
miniature mice or should the islet mass be reduced in miniature
mice?'' This question is difficult to answer unequivocally from
available information, but several points bear mention. First, in the
Snell and the Ames dwarf growth hormone-deficient mouse models, islet
mass is reduced in concert with body size(36) . Second, the
hypoglycemia observed in the RIP-PTHrP mouse per se would be
expected to reduce islet proliferation rates and thereby reduce, not
increase, islet mass. Third, in preliminary studies, RIP-PTHrP mice of
all ages and sizes are hypoglycemic and
hyperinsulinemic.()Thus, it is difficult to avoid the
conclusion that islet mass is inappropriately and absolutely increased
in the RIP-PTHrP mouse.
The second question is, ``Is a 2-fold
increase in islet mass sufficient to cause hyperinsulinemia and
hypoglycemia in otherwise normal mice?'' Again, this question is
difficult to answer from available data. Islet transplant experiments
in which pancreatic islets have been harvested from syngeneic animals
and transplanted into normal rats and mice in order to produce models
of hyperinsulinemia and hypoglycemia have generally employed more than
double the normal allotment of islets, but the viability of the
transplanted islets is difficult to know in such studies and could
conceivably be such that a 2-fold increase in islet mass was achieved.
In patients with insulinomas, islet mass is probably not more than
double, but insulinomas have intrinsic glucose sensing and insulin
secretory abnormalities that account for insulin
oversecretion(37) . Our bias would be that a 2-fold increase in
islet mass should be insufficient for the induction of hypoglycemia,
and that despite the perifusion study results, suggesting that glucose
sensing and the regulation of insulin secretion are normal, the
RIP-PTHrP islets or individual cells have intrinsic
glucose-sensing or insulin regulatory abnormalities that lead to
inappropriate insulin secretion, and that were not detected using our
perifusion method. In preliminary studies, we have found that
administration of synthetic PTHrP(1-36) or PTHrP(1-74) by
perifusion to normal islets does not influence insulin secretion.
Clarification of these possiblities must await further study.
PTHrP
is produced in a broad range of normal tissues. It has been shown to
have important effects on growth, development, and differentiation in
many tissues (reviewed in (1, 2, 3, 4, 5, 6) and 13),
including the epidermal keratinocyte, the osteoblast, the chondrocyte,
the fibroblast, the mammary myoepithelial cell, the renal proximal
tubular cell, embryonic teratoma cells, and others. No studies have
been reported examining the possible role of PTHrP as a mitogen, or
developmental or differentiating factor in the pancreatic islet.
However, Drucker and collaborators have shown that butyrate, which
induces differentiation in cultured pancreatic cell lines,
co-induced the expression of PTHrP in these cells(38) . The
increased pancreatic islet cell mass in the RIP-PTHrP mouse is
consistent with a role for PTHrP as a factor that regulates islet cell
mass. It is worth noting that disruption of the PTHrP gene has been
accomplished in a mouse model by Karaplis and colleagues(16) .
The ``PTHrP knockout'' mouse has severe skeletal
abnormalities. Unfortunately, however, these animals die immediately
following parturition, prior to the complete development of pancreatic
islets. This early lethality together with the absence of information
regarding insulin and glucose homeostasis in these animals means that
the consequences of PTHrP gene disruption on islet formation and
function remain unknown in these animals. Further studies will be
required to determine whether PTHrP is in fact a growth regulatory
peptide in the islet, and if so, whether these effects occur primarily
developmentally in utero or continue into adult life. The
potential role for PTHrP as an islet growth factor is significant given
the failure of the
cell in Type II diabetes mellitus, given the
long term failure of islet cell transplantation despite the development
of potent and effective immunosuppressive agents, and given the current
paucity of well defined islet growth factors.
PTHrP is a prohormone that is posttranslationally endoproteolytically cleaved to yield a family of mature secretory peptides(3, 4, 5) . These include an amino-terminal secretory form, which binds to and activates the recently cloned parathyroid hormone receptor(10) , as well as several other mid-region, and carboxyl-terminal secretory forms of the peptide. In the current experiment, since the full-length PTHrP(1-141) cDNA was used to construct the transgene, these experiments do not provide information regarding which of the several secretory forms is (or are) responsible for the hyperinsulinemia and islet hyperplasia observed.
The dwarfed phenotype was particularly
surprising given the presence of hyperinsulinemia. In preliminary
studies, RIP-PTHrP mice are dwarfed as compared to their littermates
throughout their normal lifespan. The animals are healthy
and vigorous-appearing throughout life, are not hypercalcemic, and have
no organ or tissue abnormalities at post-mortem examination.
Furthermore, none of the several other RIP transgenic models described
to date have displayed dwarfism as a part of the
phenotype(19, 20, 30, 31, 32, 33, 34) .
Thus, it is likely that dwarfism occurs not as an artifactual result of
the transgene but as a specific consequence of PTHrP overexpression.
Plasma IGF-1 concentrations were strikingly reduced, and these in turn
would appear to have resulted from a similarly striking reduction in
growth hormone. It seems likely that dwarfism results from low level
``leaky'' expression of the transgene in the hypothalamus or
pituitary (low levels of transgene expression were observed in tissues
outside the islet in the RIP-PTHrP mouse as they have in other RIP-
transgenic mice; see Refs. 19, 20, and 31-35). Northern analysis
of pituitary RNA failed to detect PTHrP mRNA in either normal or
transgenic pituitary (not shown). PTHrP is slightly overexpressed in
RNA prepared from whole brain of the transgenic animals (Fig. 3), but it is not yet clear whether there is
overexpression of PTHrP in the hypothalamus. If overexpression were to
occur in the hypothalamus, it would suggest that PTHrP may inhibit
growth hormone or GHRH production or secretion, and would imply that
PTHrP might play a normal physiologic role in their regulation. Studies
designed to clarify these issues are under way. In the context of the
current study, however, growth hormone deficiency or consequent
insulin-like growth factor I deficiency would not be expected to lead
to hyperinsulinemia, hypoglycemia and islet hyperplasia. Thus, the
growth abnormality is almost certainly independent from the glucose
homeostatic abnormalities observed.
In summary, these studies indicate that PTHrP may play a normal physiologic role as a regulator of islet cell mass, and through this mechanism or perhaps others, may play a normal role in the physiologic regulation of insulin secretion. Further studies are required to define the cellular mechanisms underlying the islet mass-regulating properties of PTHrP, to define the developmental pathobiology of the pancreas and glucose homeostasis in the RIP-PTHrP mouse, and to fully define the mechanisms responsible for dwarfing.