Spermiogenesis and exchange of basic nuclear proteins are impaired in male germ cells lacking Camk4.

Ca2+/calmodulin-dependent protein kinase IV (Camk4; also known as CaMKIV), a multifunctional serine/threonine protein kinase with limited tissue distribution, has been implicated in transcriptional regulation in lymphocytes, neurons and male germ cells. In the mouse testis, however, Camk4 is expressed in spermatids and associated with chromatin and nuclear matrix. Elongating spermatids are not transcriptionally active, raising the possibility that Camk4 has a novel function in male germ cells. To investigate the role of Camk4 in spermatogenesis, we have generated mice with a targeted deletion of the gene Camk4. Male Camk4-/- mice are infertile with impairment of spermiogenesis in late elongating spermatids. The sequential deposition of sperm basic nuclear proteins on chromatin is disrupted, with a specific loss of protamine-2 and prolonged retention of transition protein-2 (Tnp2) in step-15 spermatids. Protamine-2 is phosphorylated by Camk4 in vitro, implicating a connection between Camk4 signalling and the exchange of basic nuclear proteins in mammalian male germ cells. Defects in protamine-2 have been identified in sperm of infertile men, suggesting that our results may have clinical implications for the understanding of human male infertility.

Cyclic AMP second messenger systems.

Cells carefully regulate the generation and destruction of cAMP using diverse families of adenylate cyclases and phosphodiesterases. Genes for several cyclases have now been cloned, giving structural information about the enzymes and providing access to the remaining members of this family. A much larger family of phosphodiesterases has been uncovered and the regulatory properties of both the cyclases and phosphodiesterases provide diverse mechanisms to modulate intracellular cAMP. Most of the actions of cAMP are mediated through phosphorylation of substrates of the cAMP-dependent protein kinases. Recent progress has helped define the pathway between cAMP and the activation of gene transcription.

A chicken transferrin gene in transgenic mice escapes X-chromosome inactivation.

Mammalian X-chromosome inactivation involves a coordinate shutting down of physically linked genes. Several proposed models require the presence of specific sequences near genes to permit the spread of inactivation into these regions. If such models are correct, one might predict that heterologous genes transferred onto the X chromosome might lack the appropriate signal sequences and therefore escape inactivation. To determine whether a foreign gene inserted into the X chromosome is subject to inactivation, transgenic mice harboring 11 copies of the complete, 17-kilobase chicken transferrin gene on the X chromosome were used. Male mice hemizygous for this insert were bred with females bearing Searle's translocation, an X-chromosome rearrangement that is always active in heterozygous females (the unrearranged X chromosome is inactive). Female offspring bearing the Searle's translocation and the chicken transferrin gene had the same amount of chicken transferrin messenger RNA in liver as did transgenic male mice or transgenic female mice lacking the Searle's chromosome. This result shows that the inserted gene is not subject to X-chromosome inactivation and suggests that the inactivation process cannot spread over 187 kilobases of DNA in the absence of specific signal sequences required for inactivation.

Distinct patterns of cAMP-dependent protein kinase gene expression in mouse brain.

In situ hybridization was used to localize cAMP-dependent protein kinase (PKA) mRNAs in the adult mouse CNS. The PKA holoenzyme contains two catalytic (C) subunits and a regulatory (R) subunit dimer. Our studies demonstrate expression of two isoforms of C (C alpha and C beta) and four isoforms of R (RI alpha, RI beta, RII alpha, and RII beta) in the CNS. mRNAs for C alpha, RI alpha, and RI beta preferentially localize in the neocortex, caudate-putamen, hypothalamus, thalamus, and hippocampus. Hybridization with C beta and RII beta probes is clearly distinguished from the C alpha-like pattern by a reduced level of hybridization in the thalamus and by a relative increase in expression in the dentate gyrus compared with cell layers CA1-3 in the hippocampus. RII alpha transcripts are very specifically localized in the medial habenula. The differential expression of PKA subunit genes suggests that functional differences in cAMP responses within neural tissues may be mediated by the biochemical properties of specific PKA isoforms.

Estrogen regulation of the avian transferrin gene in transgenic mice.

The intact chicken transferrin gene was microinjected into fertilized mouse eggs, and the resulting transgenic animals were used to produce lines of mice containing integrated copies of the chicken gene. The levels of expression of the chicken gene were quantitated in various tissues, and the response of the gene to estrogen stimulation was measured after chronic or acute estrogen exposure. Two of the three mouse lines studied maintained stable levels of expression in successive generations of offspring, and the third line had two- to threefold-higher levels in offspring than in the original parent. In the third line, the original transgenic parent was found to be a mosaic. The chicken transferrin gene was expressed at 10- to 20-fold-higher levels in liver than in any other tissue; however, the levels of chicken transferrin mRNA in kidney were higher than expected, indicating that the tissue specificity was only partial. In all three lines, the foreign gene was induced by estrogen administration. After 10 days of estrogen administration, there was a twofold increase in both transferrin mRNA and transcription of the chicken transferrin gene. A single injection of estradiol led to a fourfold increase in transferrin mRNA synthesis at 4h. As a control the levels of mouse albumin were measured, and both the level of albumin mRNA and its rate of transcription declined about twofold after estrogen administration. Our results indicate that the intact chicken gene with 2.2 kilobases of 5' flanking sequence contains signals for both tissue specificity and steroid regulation that can be recognized in mice.

Expression from the transferrin gene promoter in transgenic mice.

Transferrin is an iron-binding protein that is expressed as a major product in liver and secreted into the plasma. To study the tissue-specific regulatory regions of this gene, the genomic mouse transferrin (mTf) gene was cloned and characterized by partial sequence analysis and S1 nuclease mapping of the transcriptional start site. Fusion genes containing the transferrin gene promoter and 5'-flanking sequences were ligated to the human growth hormone (hGH) gene and used to produce transgenic mice. A deletion construct containing the -581 to +50 region of the transferrin gene was sufficient to direct a high level of liver-specific expression resembling endogenous transferrin gene expression. Deletion to -139 base pairs of 5'-flanking sequence gave a construct which retained liver specificity, but the magnitude of expression decreased severalfold. These results demonstrate the presence of a liver-specific transcriptional element between -139 and +50 and suggest the presence of a distal element between -581 and -139 that can further increase expression. Surprisingly, fusion constructs containing -3 kilobase pairs (kb) of 5'-flanking sequence gave higher levels of mRNA in nonhepatic tissues than did either the -581 or -139 construct. Further studies indicated that the high levels of circulating hGH in these transgenic mice specifically induced the endogenous transferrin and albumin genes in liver and also stimulated the normally low levels of expression of the endogenous transferrin gene in brain, heart, kidney, and muscle. A mutated hGH gene that does not produce active growth hormone was fused to the -3- to +50-kb transferrin sequences to produce the -3-kb mTf-hGX construct. A liver-specific pattern of expression was observed in transgenic mice harboring the -3-kb mTf-hGX construct, and this mutated transgene was shown to be induced four- to sevenfold by either bovine or human growth hormone. These results demonstrate the presence of a growth hormone-responsive element between -3 and +50 kb in the 5'-flanking region of the mTf gene promoter.

A C/EBP-binding site in the transferrin promoter is essential for expression in the liver but not the brain of transgenic mice.

The gene for the iron-binding protein transferrin is transcribed at a high level in liver hepatocytes but is also active in several other cell types, including oligodendrocytes in the brain. Enhancer elements between bp -560 and -44 of the transferrin gene promoter specifically activated transcription from a heterologous promoter in transgenic mouse liver and brain. Within this region, a potent cis-acting element between bp -98 and -83 was found to be essential for gene activity in both cultured hepatocytes and transgenic mouse liver. The -98 to -83 element contains a CCAAT sequence and is specifically bound by a nuclear factor from mouse liver that is homologous to rat liver C/EBP (CAAT enhancer-binding protein). Point mutations within this binding site inhibit factor binding and abolish transcription in transfected hepatoma cells. When placed in the context of the 3,000-bp transferrin promoter, the C/EBP binding site mutation causes a complete loss of transcription in transgenic mouse liver; however, transgene expression in the brain of the same animals was unaffected. These results suggest a modular structure for the transferrin promoter and demonstrate that deletions or specific point mutations can be used to generate transgene promoters with an activity more restricted than that of their endogenous counterparts.

Calcium/calmodulin-dependent protein kinase types II and IV differentially regulate CREB-dependent gene expression.

Phosphorylation of CREB (cyclic AMP [cAMP]- response element [CRE]-binding protein) by cAMP-dependent protein kinase (PKA) leads to the activation of many promoters containing CREs. In neurons and other cell types, CREB phosphorylation and activation of CRE-containing promoters can occur in response to elevated intracellular Ca2+. In cultured cells that normally lack this Ca2+ responsiveness, we confer Ca(2+)-mediated activation of a CRE-containing promoter by introducing an expression vector for Ca2+/calmodulin-dependent protein kinase type IV (CaMKIV). Activation could also be mediated directly by a constitutively active form of CaMKIV which is Ca2+ independent. The CaMKIV-mediated gene induction requires the activity of CREB/ATF family members but is independent of PKA activity. In contrast, transient expression of either a constitutively active or wild-type Ca2+/calmodulin-dependent protein kinase type II (CaMKII) fails to mediate the transactivation of the same CRE-containing reporter gene. Examination of the subcellular distribution of transiently expressed CaMKIV and CaMKII reveals that only CaMKIV enters the nucleus. Our results demonstrate that CaMKIV, which is expressed in neuronal, reproductive, and lymphoid tissues, may act as a mediator of Ca(2+)-dependent gene induction.

Deficient gene expression in protein kinase inhibitor alpha Null mutant mice.

Protein kinase inhibitor (PKI) is a potent endogenous inhibitor of the cyclic AMP (cAMP)-dependent protein kinase (PKA). It functions by binding the free catalytic (C) subunit with a high affinity and is also known to export nuclear C subunit to the cytoplasm. The significance of these actions with respect to PKI's physiological role is not well understood. To address this, we have generated by homologous recombination mutant mice that are deficient in PKIalpha, one of the three isoforms of PKI. The mice completely lack PKI activity in skeletal muscle and, surprisingly, show decreased basal and isoproterenol-induced gene expression in muscle. Further examination revealed reduced levels of the phosphorylated (active) form of the transcription factor CREB (cAMP response element binding protein) in the knockouts. This phenomenon stems, at least in part, from lower basal PKA activity levels in the mutants, arising from a compensatory increase in the level of the RIalpha subunit of PKA. The deficit in gene induction, however, is not easily explained by current models of PKI function and suggests that PKI may play an as yet undescribed role in PKA signaling.

PKA isoforms, neural pathways, and behaviour: making the connection.

In mammals, the cAMP-dependent protein kinase (PKA) family of enzymes is assembled from the products of four regulatory and two catalytic subunit genes, all of which are expressed in neurons. Specific isoforms of PKA display differences in biochemical properties and subcellular localization, but it has been difficult to ascribe specific physiological functions to any given isoform. The recent development of gene knockout and transgenic mouse models has allowed for a more integrated examination of the in vivo roles of specific PKA isoforms in gene expression, synaptic plasticity, and behaviour.

High ethanol consumption and low sensitivity to ethanol-induced sedation in protein kinase A-mutant mice.

Both in vitro and in vivo evidence indicate that cAMP-dependent protein kinase (PKA) mediates some of the acute and chronic cellular responses to alcohol. However, it is unclear whether PKA regulates voluntary alcohol consumption. We therefore studied alcohol consumption by mice that completely lack the regulatory IIbeta (RIIbeta) subunit of PKA as a result of targeted gene disruption. Here we report that RIIbeta knockout mice (RIIbeta-/-) showed incr eased consumption of solutions containing 6, 10, and 20% (v/v) ethanol when compared with wild-type mice (RIIbeta+/+). On the other hand, RIIbeta-/- mice showed normal consumption of solutions containing either sucrose or quinine. When compared with wild-type mice, the RIIbeta-/- mice were found to be less sensitive to the sedative effects of ethanol as measured by more rapid recovery from ethanol-induced sleep, even though plasma ethanol concentrations did not differ significantly from those of controls. Finally, both RIbeta- and catylatic subunit beta1-deficient mice showed normal voluntary consumption of ethanol, indicating that increased ethanol consumption is not a general characteristic associated with deletion of PKA subunits. These data demonstrate a role for the RIIbeta subunit of PKA in regulating voluntary consumption of alcohol and sensitivity to the intoxication effects that are produced by this drug.

Mutation of the RIIbeta subunit of protein kinase A prevents diet-induced insulin resistance and dyslipidemia in mice.

The mechanisms by which obesity contributes to diabetic phenotypes remain unclear. We evaluated the role of protein kinase A (PKA) signaling events in mediating diabetes associated with obesity. PKA comprises two regulatory subunits and two catalytic subunits and is activated by cAMP. The RIIbeta regulatory subunit is abundantly expressed in adipose tissue and brain. Knockout mice lacking this subunit are lean and display remarkable resistance to diet-induced obesity. We investigated whether these mice were also resistant to diet-induced diabetes and whether this effect was dependent on reduced adiposity. Mice were fed a high-fat, high-carbohydrate diet and weight gain and diabetes phenotypes were examined. RIIbeta(-/-) mice displayed decreased body weights, reduced insulin levels, improved insulin sensitivity, and improved total-body glucose disposal as compared with wild-type controls. Plasma levels of VLDL and LDL cholesterol were also reduced in high fat-fed RIIbeta(-/-) mice compared with wild-type mice. Taken together, these data demonstrate that loss of RIIbeta protects mice from diet-induced obesity, insulin resistance, and dyslipidemia.

Role of cyclic adenosine 3',5'-monophosphate-dependent protein kinase in hormone-stimulated beta-endorphin secretion in AtT20 cells.

Secretion of beta-endorphin from mouse pituitary AtT20 cells is stimulated by a variety of compounds that raise intracellular cAMP and Ca2+. To investigate the role of cAMP-dependent protein kinases in secretion, AtT20 cells were transfected with an expression vector coding for a regulatory (R) subunit of cAMP-dependent protein kinase containing mutations in both cAMP-binding sites. Expression of the mutant regulatory subunit in stable transformants (RAB cells) results in a dominant inhibition of cAMP-dependent protein kinase activity. Isoproterenol (1 microM) or analogs of cAMP stimulated beta-endorphin secretion from AtT20 cells, but failed to stimulate secretion in RAB cells expressing the mutant R subunit. Secretion in response to CRF (100 nM) was inhibited by 80% in these mutant clones, whereas the secretory response to vasoactive intestinal peptide (VIP; 100 nM) or phorbol ester (100 nM phorbol myristate acetate) was not inhibited by the R subunit mutation. Intracellular cAMP was elevated in response to CRF (11- to 15-fold), isoproterenol (5- to 10-fold), and VIP (4- to 8-fold) in RAB cells. Similar concentrations of VIP were required to evoke beta-endorphin secretion in either RAB cells or AtT20 cells. As with most secretagogues, VIP-induced secretion was inhibited in the presence of either EGTA or a voltage-sensitive Ca2+ channel antagonist, PN200-110. The secretory response to VIP was unaffected by down-regulation of protein kinase-C. These results suggest that CRF and isoproterenol work via cAMP-dependent protein kinase to activate beta-endorphin secretion, whereas VIP can act by a different mechanism that does not involve cAMP-dependent protein kinase or protein kinase-C.

The MMTV LTR promoter is induced by progesterone and dihydrotestosterone but not by estrogen.

Induction of the mouse mammary tumor virus (MMTV) promoter by steroid hormones was examined in chick oviduct primary cell cultures transfected with MMTV-chloramphenicol acetyl transferase fusion constructs. Our results demonstrate that in this system glucocorticoids, progesterone and dihydrotestosterone are all able to stimulate MMTV transcription; induction by progesterone and dihydrotestosterone is not mediated by glucocorticoid receptors, since the specific glucocorticoid antagonist RU486 did not inhibit the response. In contrast, estrogen does not stimulate MMTV transcription, although estrogen does induce the endogenous ovalbumin gene in the same cells. While progesterone effects are mediated by the same response elements within the MMTV long terminal repeat that were originally characterized for the glucocorticoid receptor, an androgen response element has not yet been defined. Our data indicate that the MMTV long terminal repeat does not contain an estrogen response element.

Promoter for the regulatory type I beta subunit of the 3',5'-cyclic adenosine monophosphate-dependent protein kinase directs transgene expression in the central nervous system.

Cyclic AMP-dependent protein kinase (cAPK) modulates synaptic transmission and influences memory and learning. Among the various isoforms of regulatory and catalytic subunits that comprise mammalian cAPK, only the regulatory type I beta (RI beta) subunit is unique to nervous tissue. The requirement for RI beta in neurons is presently unknown. Previous studies demonstrate that holoenzyme containing RI beta activates at lower concentrations of cAMP compared to other forms of cAPK. Thus, neurons that induce RI beta expression may become more sensitive to subsequent hormonal signals and maintain more long-term phosphorylation events. To further elucidate the function of this novel protein, we have begun to investigate its gene. Here we report the isolation of the mouse RI beta promoter as determined by S1 nuclease analysis and transgenic mouse expression. A beta-galactosidase fusion gene containing 1.5 kilobases of 5'-nontranscribed RI beta DNA and 2 kilobases of intron 1 was expressed preferentially in the cortex and hippocampus of the brain and within the spinal cord. In addition to mimicking the location of endogenous RI beta expression, the transgene was activated at a similar time (embryonic day 11.5) during mouse fetal development. Isolation of the RI beta promoter will help identify the elements that direct transcription in a subset of neurons and illuminate the physiological conditions that may regulate RI beta expression. This promoter can also be used to target the expression of wild type and mutant cAPK subunit genes in order to investigate synaptic plasticity in animals.

Chicken egg white genes: multihormonal regulation in a primary cell culture system.

A primary cell culture from estrogen-withdrawn chicken oviduct has been developed in which the genes for the major egg white proteins, ovalbumin and conalbumin, are induced by steroid hormones. The responsiveness of the isolated cells depends on the combination of enzymes employed to dissociate the oviduct; trypsin and pronase are essential. Administration of estradiol to cultured cells is insufficient to induce ovalbumin mRNA (mRNAov) to levels achieved in vivo. Both insulin and a second steroid (a glucocorticoid, progestin, or androgen) are required for the induction of the ovalbumin gene by estradiol to the extent reached in vivo. Although low levels of a progestin or androgen can synergize with estradiol to obtain an induction of mRNAov, we have demonstrated that a physiological concentration of corticosterone (10(-8) M) potentiates a large response to estradiol without causing an induction when added alone. When estradiol, corticosterone, and insulin are present in the culture medium, mRNAov increases from about 20 to 6500 molecules/cell by 55 h. With the same culture conditions, conalbumin mRNA increases from about 120 to 4300 molecules/cell by 52 h. After about 55 h, the level of egg white mRNAs decreases, and this reduction in mRNAov correlates with a diminished transcription of that gene. The data obtained with the cultured cells demonstrate that the induction of the ovalbumin gene requires the permissive effects of insulin and a second steroid (probably a glucocorticoid in vivo) to facilitate the response to estradiol.

Regulation of the ovalbumin gene: effects of insulin, adenosine 3',5'-monophosphate, and estrogen.

Induction of the ovalbumin gene in chicken oviduct explant cultures requires the presence of a serum component in addition to estrogen. Previous studies have demonstrated that either insulin or related peptides, such as proinsulin or insulin-like growth factor, can eliminate the requirement for serum. In the present study, we determined that half-maximal binding of [125I]iodoinsulin to oviduct cell membranes occurs with 5 X 10(-10) M insulin, and proinsulin is 10-fold less effective than insulin as a competitor. Induction of the ovalbumin gene is half-maximal with 10(-9) M insulin, and both proinsulin and insulin-like growth factor are 10-fold less potent. These results suggest that insulin is the physiological hormone that is required in addition to estrogen to stimulate transcription of the ovalbumin gene. In an effort to understand the mechanism by which insulin regulates the steroid response in this system, we searched for agents that could substitute for insulin. We found that cyclic nucleotide derivatives, such as 8-bromo-cAMP, can mimic the effect of insulin on ovalbumin gene expression and that the phosphodiesterase inhibitor isobutylmethylxanthine can potentiate this response to 8-bromo-cAMP. Activation of oviduct adenylate cyclase with either forskolin or cholera toxin also allows the estrogen-mediated induction of mRNA, and both of these agents produce a dramatic rise in intracellular cAMP. Although these results suggest that the effect of insulin on gene regulation might depend on a cAMP-mediated mechanism, we are unable to detect any change in cellular cAMP levels in response to insulin. We conclude that insulin and cAMP are producing their effects on activation of the ovalbumin gene via convergent pathways. The involvement of an activator of protein kinase, cAMP, strongly suggests that protein phosphorylation events play a regulatory role in the expression of the ovalbumin gene.

Tissue distribution and hormonal regulation of messenger ribonucleic acid for regulatory and catalytic subunits of adenosine 3',5'-monophosphate-dependent protein kinases during ovarian follicular development and luteinization in the rat.

cDNA probes specific for the regulatory (R) subunits [RII51; (mol wt, 51,000) and RI (mol wt, 49,000)] and a catalytic (C alpha) subunit of cAMP-dependent protein kinases were used to analyze the hormonal regulation, tissue distribution, and content of mRNAs for these kinase subunits in the rat ovary. Filter hybridization assays demonstrated that mRNA specific for RII51 increased in both thecal and granulosa cells of preovulatory (PO) follicles, then declined precipitously (less than 10-fold) in both cell types within 7 h after an ovulatory (10-IU) dose of hCG and remained low in corpora lutea. Dose-response studies showed that doses of FSH greater than 2 micrograms were required to increase RII51 mRNA in granulosa cells of hypophysectomized (H) rats, whereas doses of 0.5-1.0 micrograms were effective in granulosa cells of H estradiol-treated (HE) rats. At all doses (0.5-50 micrograms) of FSH administered, RII51 mRNA was 4 times higher in granulosa cells of HE rats than in H rats. Solution hybridization assays demonstrated that the concentration of RII51 mRNA increased 6-fold from 20 molecules/granulosa cell in H rats to 120 molecules/cell in H rats treated with estradiol and FSH (HEF). Transcription assays using nuclei of granulosa cells demonstrated further that the 5- to 10-fold increases in RII51 mRNA content in estradiol-/FSH-induced granulosa cells was associated with increased transcription of the RII51 gene. In thecal cells of small antral (SA), PO, and luteinizing follicles, changes in the content of mRNA for RI and C alpha kinase subunits showed a pattern similar to that for RII51. However, in granulosa cells, mRNA specific for RI and C alpha was highest in SA follicles, declined in PO follicles, and remained unchanged during luteinization. The content of mRNA for RI (45-70 molecules/cell) and C alpha (10 molecules/cell) also changed less than 2-fold in granulosa cells of H, HE, and HEF rats. In summary, these results indicate that the content of RII51 mRNA is hormonally regulated in both thecal cells and granulosa cells during follicular development and luteinization. Low concentrations of gonadotropins increase RII51 mRNA, whereas an ovulatory dose of hCG causes mRNA for RII51 to decrease rapidly. In granulosa cells, induction of mRNA for RII51, but not that for RI and C alpha is induced by the actions of estradiol and FSH, and involves increased transcription of the RII51 gene.

Transferrin messenger ribonucleic acid: molecular cloning and hormonal regulation in rat Sertoli cells.

Transferrin-specific cDNA clones were isolated from a rat liver cDNA library prepared from transferrin-enriched mRNA. Hybrid selection and sequence analysis confirmed that the selected clone contained the carboxy-terminal coding region of the transferrin mRNA. Northern blot analysis was used to demonstrate the presence of transferrin mRNA in liver and Sertoli cells. Transferrin mRNA levels were measured in total RNA isolated from cultured rat Sertoli cells after treatment with FSH, insulin, retinol, and testosterone. The results showed a 2- to 4-fold increase in the level of transferrin mRNA, which peaked on the fourth day of culture after initiation of treatment, with FSH, insulin, retinol, and testosterone. This induction is gene specific, since no change in the mRNA levels for either the catalytic or regulatory subunits of cAMP-dependent protein kinase was observed. The effects of hormones, vitamin A (retinol), and Bu2 cAMP on transferrin mRNA and transferrin secretion (measured by RIA) in cultured Sertoli cells were compared. In general, a direct relationship between the amount of transferrin mRNA present in the cells and the amount of transferrin secreted into the culture medium was observed. These results demonstrate the important role that vitamin A, testosterone, and peptide hormones play in modulating transferrin gene expression in Sertoli cells.

A unique mRNA species for a regulatory subunit of cAMP-dependent protein kinase is specifically induced in haploid germ cells.

Cyclic AMP (cAMP) and its action by way of cAMP-dependent protein kinase is important for sperm motility. Previous studies on germ cells have demonstrated a selective decrease in the amount of type I cAMP-dependent protein kinase during spermatid development, and that type II was the major form present in elongating spermatids and in mature sperm. This would indicate activation of a gene in haploid germ cells, encoding a regulatory subunit of type II protein kinase. However, haploid expression of such a gene has so far not been shown. In the present study we demonstrate high-levelled expression of a unique mRNA species for a specific regulatory subunit of type II cAMP-dependent protein kinase at late stages of spermatogenesis, i.e. during spermatid elongation.