Postembryonic expression of the myosin heavy chain genes in the limb, tail, and heart muscles of metamorphosing amphibian tadpoles.

Thyroid hormone is presumed to play a role in initiating and/or orchestrating the postembryonic expression of the genes encoding isoforms of the myosin heavy chains (MHCs) that characterize the muscle fibres in an adult organism. The fact that the postembryonic development of a free-living amphibian tadpole takes place during its thyroid hormone-dependent metamorphosis has made the metamorphosing tadpole an ideal system for elucidating the molecular mechanism(s) by which this hormone affects these postembryonic changes. In this review, we summarize the results from recent studies focused on the postembryonic expression of the MHC genes in the skeletal muscles and hearts of metamorphosing anuran (Rana catesbeiana) tadpoles. The demonstration that mRNAs encoding at least five of the MHC isoforms present in the tadpole tail muscles are also present in the adult hind-limb muscles and that an mRNA encoding a cardiac-specific MHC isoform is present in the heart of both the tadpole and adult organism, rules out the possibility that thyroid hormone initiates the expression of these MHC genes. Instead, it seems more likely that this hormone acts by modulating the expression of one or more of the genes encoding these particular MHC isoforms. Whatever the case, the fact that sequence homology suggests that the five distinct skeletal muscle-specific MHCs are all "fast" isoforms raises the question of how these MHCs are distributed among the three different fibre types described for Rana. On the other hand, the possibility exists that the mRNAs for one or more of these fast MHC isoforms encode developmental isoforms that are present but not translated in the muscles of the tadpole and/or adult frog. Finally, an evaluation of the evolutionary relatedness of the R. catesbeiana MHCs to the MHCs in another species of Rana and to the MHCs in other vertebrates discloses, among other things, that the nucleotide sequence in the R. catesbeiana cardiac MHC isoform is more closely related to the chicken ventricular MHC isoform than it is to any of the other MHC isoforms examined.

Expression of the myosin heavy chain genes in the tail muscle of thyroid hormone-induced metamorphosing Rana catesbeiana tadpoles.

In tadpoles of the North American bullfrog, Rana catesbeiana, spontaneous and thyroid hormone (T3)-induced metamorphosis is characterized by regression of the tail, which is preceded by a decrease in total protein synthesis in tail tissues. We have demonstrated that thyroid hormone treatment of a tadpole does not affect the synthesis of all proteins equally in the tadpole tail muscle. For example, the synthesis of myosin heavy chains (MHCs) is depressed within 1 day and decreases to 45% of control values after 5 days of T3 treatment, whereas the decreased synthesis of soluble muscle proteins is transient and returns to above control levels by day 5. To determine whether the hormone-induced decrease in MHC synthesis is the result of changes in the transcription of translation of MHC mRNAs, we isolated cDNAs complementary to five different MHC mRNAs from a tail muscle cDNA library and used them to examine the levels of each MHC mRNA in the tail muscle of T3-treated tadpoles. mRNAs that recognize the cDNAs for these five different MHCs are all expressed in the tadpole tail and limb muscles, as well as in the adult leg muscles. MHC mRNAs unique to tadpole tail were not detected. Interestingly, the relative amounts of mRNA for four of the five MHCs increase in tail muscle after T3 treatment of the tadpole, suggesting that repression of MHC gene expression at the protein level does not result from a decrease in the amount of MHC mRNAs. Rather, these results support the contention that the decreased synthesis of MHCs in the tail muscle of T3-treated tadpoles is caused by this hormone, either directly or indirectly, depressing the translation of the MHC mRNAs in this tissue. These results, coupled with the observation that the synthesis of soluble muscle proteins is depressed only in a transient fashion, suggest that T3 may be initiating the expression of a gene(s) that encodes a protein(s) responsible for inhibiting the translation of the MHCs and, perhaps, other structural proteins in the tadpole tail muscle. Whatever the case, the translational regulation of MHC synthesis occurs well before any degradation of the tail tissue is evident and appears to be one of the earliest events in the hormone-induced cell death program of the tadpole tail muscle.

Thyroid hormone induces a reprogramming of gene expression in the liver of premetamorphic Rana catesbeiana tadpoles.

During spontaneous or thyroid hormone-induced metamorphosis of the Rana catesbeiana tadpole, postembryonic changes occur in its liver that are permanent and necessary for the transition of this organism from an aquatic, ammonotelic larva to a semiterrestrial, ureotelic adult. These changes include the coordinated expression of genes encoding the urea cycle enzymes carbamyl phosphate synthetase and ornithine transcarbamylase. Although these changes are dependent on thyroid hormone and occur within the resident hepatocytes, the mechanism(s) by which this hormone reprograms gene expression in these cells and initiates the tissue-specific expression of these genes is poorly understood. Our contention is that the thyroid hormone-induced expression of these genes is an indirect effect of thyroid hormone and involves an early, thyroid hormone-induced upregulation of a gene(s) encoding a tissue-specific transcription factor(s), which in turn, upregulates in a coordinated fashion, the expression of these urea cycle enzyme genes. Herein, we present results that demonstrate a role for a Rana homologue of a mammalian transcription factor, C/EBPalpha(designated as RcC/EBP-1), in the thyroid hormone-induced cascade of gene activity responsible for reprogramming gene expression and initiating the coordinated expression of genes, such as carbamyl phosphate synthetase-I and ornithine transcarbamylase, which are characteristic of the adult liver phenotype.

Translation of some maize small heat shock proteins is initiated from internal in-frame AUGs.

Etiolated maize radicles (inbred Oh43) subjected to a brief heat shock synthesize a family of small heat shock proteins (approximately 18 kD) that is composed of at least 12 members. We previously described the cDNA-derived sequence of three maize shsp mRNAs (cMHSP18-1, cMHSP18-3, and cMHSP18-9). In this report, we demonstrate that the mRNA transcribed in vitro from one of these cDNAs (cMHSP18-9) is responsible for the synthesis of three members of the shsp family, and we suggest that cMHSP18-3 may be responsible for the synthesis of three additional members and cMHSP18-1 for the synthesis of two other members of this family. The fact that these genes do not contain introns, coupled with the observations reported herein, suggest that maize may have established another method of using a single gene to produce a number of different proteins.

Role for the Rana catesbeiana homologue of C/EBP alpha in the reprogramming of gene expression in the liver of metamorphosing tadpoles.

During the spontaneous or thyroid hormone (TH)-induced metamorphosis of Rana catesbeiana, developmental changes occur in its liver that are necessary for the transition of this organism from an ammonotelic larva to a ureotelic adult. These changes include the coordinated expression of genes encoding the urea cycle enzymes carbamyl phosphate synthetase (CPS-I) and arnithine transcarbamylase (OTC). Although the expression of these genes is dependent on TH, the mechanisms(s) by which TH initiates this tissue-specific response is thought to be indirect and to involve early TH-induced upregulation of a gene(s), which, in turn, upregulates the coordinated expression of these urea-cycle enzyme genes. Herein, we demonstrate that mRNAs encoding the Rana homologue of the mammalian transcription factor C/EBP alpha (designated RcC/EBP-1) accumulate early in response to TH and that the product of these mRNAs can bind to and transactivate the promoters of both the Rana CPS-1 and OTC genes. These results support the contention that the reprogramming of gene expression in the liver of metamorphosing tadpoles involves a TH-induced cascade of gene activity in which RcC/EBP-1 and, perhaps, other transcription factors coordinate the expression of genes, such as those encoding CPS-I and OTC, whose products are characteristic of the adult liver phenotype.

The promoter region of the carbamoyl-phosphate synthetase III gene of Squalus acanthias.

Carbamoyl-phosphate synthetase III (CPSase III) of Squalus acanthias (spiny dogfish) is a nuclear-encoded mitochondrial enzyme that catalyzes glutamine-dependent formation of carbamoyl phosphate for urea synthesis. In this paper we report the results of cloning a 10-kb segment of genomic DNA which includes the region flanking the 5' end of the spiny dogfish CPSase III gene. A total of 1,295 base pairs of sequence straddling the start codon was obtained. Primer extension experiments revealed that the transcription start site is the G located 114 residues upstream of the translation start codon ATG. The first exon has 240 base pairs, including the 5' untranslated region, the coding sequence for the signal peptide (38 amino acids), and the four N-terminal amino acids of the mature enzyme. The boundary of the first exon and the first intron of the CPSase III gene is concordant with that of rat and frog (Rana catesbeiana) CPSase I, which have been suggested to have evolved from CPSase III. The putative TATA box sequence, TACAAA, is located at position -31 with an uncommonly found C at the third position. Two C/EBP binding site sequences, ATTCTGCAAG (-405 to -397) and GTGCAGTAAG (-168 to -160), were identified in the promoter region, which suggests that spiny dogfish CPSase III might be subjected to transactivation of transcription by C/EBP-related proteins, as has been reported for rat CPSase I. The preparation and binding of a recombinant RcC/EBP-1 protein (the R. catesbeiana homolog of the mammalian C/EBP alpha) to the two spiny dogfish C/EBP binding sequences are described. Two putative heat-shock binding elements were also identified in the promoter region.

Characterization of a Rana catesbeiana hsp30 gene and its expression in the liver of this amphibian during both spontaneous and thyroid hormone-induced metamorphosis.

During metamorphosis, the Rana catesbeiana tadpole undergoes developmental changes in almost every tissue/organ. These changes prepare the ammonotelic, swimming larva for its transition to a ureotelic, terrestrial adult, and involve dramatic remodeling. The postembryonic changes in this tadpole are initiated by the thyroid hormones (TH) and result in the extensive degradation of proteins and degeneration of tissues characteristic of the larval phenotype and in the de novo synthesis of proteins characteristic of the adult phenotype. We questioned whether the drastic nature and abruptness of the TH-dependent, postembryonic changes occurring in the tissues of this tadpole might be perceived by the cells in some tissues as stressful and, therefore, cause them to express heat shock and/or stress-like proteins. To address this question, we isolated and characterized a Rana catesbeiana hsp30 gene and used sequences from it to determine if mRNAs encoded from it, or other members of this gene family, are expressed in tissues of tadpoles undergoing metamorphosis. Our results demonstrate that the liver of metamorphosing Rana catesbeiana tadpoles accumulate hsp30 mRNAs and express the heat shock proteins they encode. The fact that the expression of these hsp30s in the liver of these tadpoles is coincidental with the TH-induced expression of genes encoding the liver-specific urea cycle enzymes suggests that TH may influence, directly or indirectly, the expression of these hsp30 genes and, moreover, implies that the presence of one or more of these heat shock proteins may be necessary for the developmental transitions occurring in this organ.

Maize seedlings show cell-specific responses to heat shock as revealed by expression of RNA and protein.

The cellular localization of heat-shock proteins has been described in a number of experimental animal systems but is not well defined in plant systems. Sense and antisense RNA transcripts from the open reading frame (ORF) of 18-kDa maize heat-shock protein genes were employed in in situ hybridizations of inbred Oh43 radicles and plumules to reveal the locations of their mRNAs. Localization of the specific mRNAs to the younger meristematic cells of the root-tips and shoot-tips and also to the densely cytoplasmic cells of the vasculature was observed routinely. The ORF of one of our 18-kDa genes was cloned into an expression vector, and the 161-amino acid polypeptide was used to raise antibodies. Using a Fast Red procedure, the cellular positions of the heat-shock protein-antibody conjugates were observed in sections similar to those employed in the antisense RNA in situ hybridizations. The localization of the antibody appears to parallel closely the patterns of distribution of the mRNAs.

Characterization, chromosomal mapping, and expression of different ubiquitin fusion protein genes in tissues from control and heat-shocked maize seedlings.

Organisms possess at least two multigene families of ubiquitins: the polyubiquitins, with few to several repeat units, which encode a ubiquitin monomer, and the ubiquitin fusion (or extension) protein genes, which encode a single ubiquitin monomer and a specific protein. This report provides details about two ubiquitin fusion protein genes in maize referred to as MubG7 (uwo 1) and MubG10 (uwo 2). Each has one nearly identical ubiquitin coding unit fused without an intervening nucleotide to an unrelated, 237-nucleotide sequence that encodes for a 79 amino acid protein. The derived amino acid sequences of the two fusion proteins show that they differ by five amino acids (substitution by either a serine or threonine). MubG7 maps to chromosome 8L162 and MubG10 maps to chromosome 1L131. Analyses of the role(s) of these genes in response to heat shock (1 h at 42.5 degrees C) reveal that the level of these fusion protein mRNAs in the radicles or plumules from 2-day-old seedlings does not change; however, heat shock does cause a marked reduction in the accumulation of these same gene-specific mRNAs in the radicles and plumules of 5-day-old seedlings. These data confirm the suggestion from our earlier work that there is precise modulation, in a gene-specific manner, of the response to developmental as well as environmental signals.

Characterization, chromosomal mapping, and expression of different polyubiquitin genes in tissues from control and heat-shocked maize seedlings.

Polyubiquitin transcripts accumulate in plant and animal cells following a heat shock. Most species have a few to several polyubiquitin genes; within a species, the genes may differ in nucleotide (nt) sequence and (or) the number of 228-nt repeats encoding the ubiquitin monomer. This study examines three maize (inbred Oh43) polyubiquitin genes. Two of the genes, MubG9 and MubG5, possess five repeats; the third, MubG1 possesses seven repeats. Sequence analyses of the genomic clones, MubG9 and MubG1 and a cDNA clone, MubG5, reveal that they differ primarily from each other in their nt sequences 5' and 3' to their open reading frames. MubG1 contains a 1004-base pair (bp) intron in its 5' untranslated region. Using gene-specific probes, we show that the amount of polyribosome-associated mRNA transcripts from MubG9 isolated from 2- and 5-day old plumules and radicles is unchanged by heat shock. While the amount of transcript from MubG1 and MubG5 on the polyribosomes in plumules and radicles of 2-day-old seedlings is also unchanged by heat shock, the levels of these transcripts are elevated considerably in similar tissues from heat-shocked 5-day-old seedlings. Similar or identical gene-specific probes were employed to map the genes using the recombinant inbred method. MubG9 maps to chromosome 4L position 186; MubG1 maps to 5L104 and MubG5 to 4L188. The opportunity to use gene-specific probes extends the evidence for distinct modulation (time and tissue) of polyubiquitin gene expression in maize and provides the basis for locus assignment within the genome.

Shifts in type I fiber proportion in rat hindlimb muscle are accompanied by changes in HSP72 content.

Heat-shock protein 72 (HSP72), the inducible isoform of the HSP70 family, is constitutively expressed in rat hindlimb muscles in proportion to the content of type I muscle fibers. To determine whether this relationship was maintained after fiber transformation, male Sprague-Dawley rats were treated with 3,5,3'-triiodo-DL-thyronine (T3) for 40 days or underwent surgical removal of the left gastrocnemius muscle, after which the left plantaris muscle was allowed to hypertrophy for 30 days. Hypertrophied plantaris muscles exhibited an increased number of type I fibers, type I myosin heavy-chain (MHC) protein, and HSP72 content compared with contralateral muscles. Soleus muscles from rats administered T3 exhibited an increased number of type II fibers, citrate synthase activity, and decreased HSP72 content compared with soleus muscles from controls. These results indicate that the relationship between HSP72 content and type I muscle fiber-MHC composition is maintained when muscles undergo fiber transformation and substantiate that HSP72 content in rat skeletal muscle is not directly linked to a muscle's oxidative capacity.

3,5,3'-Triiodothyronine-induced carbamyl-phosphate synthetase gene expression is stabilized in the liver of Rana catesbeiana tadpoles during heat shock.

One of many changes occurring during spontaneous and 3,5,3'-triiodothyronine (T3)-induced metamorphosis of the Rana catesbeiana tadpole is the permanent transition from an ammonotelic, aquatic larva to a ureotelic, terrestrial adult. T3-induced urea production is preceded by T3-induced elevation in the synthesis and level of liver-specific urea cycle enzymes essential for detoxication of ammonia in a terrestrial environment. This report focuses on establishing the effects heat shock (hs) has on the T3-induced expression of genes encoding three essential urea cycle enzymes. We demonstrate that hs stabilizes the intracellular existing levels of carbamyl-phosphate synthetase I (CPS I), the first enzyme in the urea cycle, while concurrently depressing its new synthesis. To establish the effects of hs on CPS I mRNA levels, we characterized cDNAs encoding an amphibian CPS I and demonstrate that it may represent an evolutionary link between microbial CPS and mammalian CPS I. Using this CPS I cDNA and other R. catesbeiana gene-specific probes, we demonstrate that hs depresses the level of T3-induced thyroid hormone receptor beta mRNAs but does not affect the level of T3-induced CPS I, ornithine transcarbamylase, and arginase mRNAs. These results support the contention that the hs response may involve the selective protection of some pre-existing mRNAs and proteins essential for an organism's survival.

Characterization and expression of C/EPB-like genes in the liver of Rana catesbeiana tadpoles during spontaneous and thyroid hormone-induced metamorphosis.

Tissue-specific changes in gene expression occur in the liver of Rana catesbeiana tadpoles undergoing metamorphosis. Many of these changes can be induced precociously by administration of thyroid hormone (TH) to a tadpole or to cultured tadpole liver. While the precise molecular means by which TH exerts a tissue-specific response is unknown, recent studies suggest that the expression of genes which are liver-specific and characteristic of the adult liver phenotype may rely on TH-induction of tissue-specific transcription factors, as well as the thyroid hormone receptor proteins. Guided by this notion, we screened our Rana catesbeiana liver cDNA library and isolated clones, RcC/EBP-1 and -2, encoding Rana homologues of a mammalian transcription factor, C/EBP (CCAAT/enhancer core binding protein), implicated in the expression of liver-specific genes and terminal differentiation of hepatocytes. Gel mobility shift assays demonstrate that the proteins synthesized from these cDNAs bind specifically to the consensus binding site for C/EBP-related proteins. Characterization of the amino acid sequence in the bZIP DNA-binding domains of these proteins suggests that RcC/EBP-1 and -2 encode Rana homologues of C/EBP alpha and delta, respectively. Hybridization analyses demonstrate that the amount of RcC/EBP-2 mRNAs in tadpole liver remains constant throughout metamorphosis, whereas RcC/EBP-1 mRNAs are up-regulated during both spontaneous and TH-induced metamorphosis. The TH-induced up-regulation of RcC/EBP-1 mRNAs precedes the up-regulation of liver-specific urea cycle enzyme mRNAs by 6 to 12 hours. These results, coupled with in situ hybridization studies, suggest that RcC/EBP-1 mRNAs encode a transcription factor which may play an early role(s) in the terminal differentiation and/or reprogramming of gene expression in this tadpole's liver cells during both spontaneous and TH-induced metamorphosis.

The independent stage-specific expression of the 18-kDa heat shock protein genes during microsporogenesis in Zea mays L.

The small (18-kDa) heat shock proteins (hsps) of maize are encoded by a complex multigene family. In a previous report, we described the genetic information from cDNAs encoding two different members of the family. In this communication, we report the isolation and characterization of cDNA and genomic clones encoding information for a third member of this hsp family (c/gMHSP18-1). DNA fragments containing nucleotide sequences common to, or specific for, each of these characterized 18-kDa genes were prepared and used as probes to assess the expression of these genes during microsporogenesis and development of the gametophyte in an inbred line of maize (Oh43). Our results demonstrate (1) that mRNA transcripts encoding the 18-kDa hsps are expressed and/or accumulate during microsporogenesis, and (2) that genes encoding two of the characterized 18-kDa hsps are expressed and/or accumulate independently, in a stage-specific manner during microsporogenesis. These observations imply that the stage-specific expression of particular 18-kDa hsp genes results from gene-specific regulation during microsporogenesis and gametophyte development rather than from an overall activation of the heat shock or stress response.

Are prosome particles formed by the disintegration of proteasomes?

Quail reticulocyte 19S "prosome" fractions isolated on sucrose density gradients contain two kinds of particles: cylindrical proteasomes and ferritin. When samples of this fraction are prepared for electron microscopy using the one-step stain protocol described in this paper, most of the particles have a rectangular image resembling the proteasome. However, when samples are prepared for electron microscopy using the two-step stain protocol described here, there are few rectangular images. Their place is taken by round particles that resemble the prosome. Thus it appears that the round, raspberry-shaped particles called prosomes and the ring-like proteasome particles may be artifacts of specimen preparation for electron microscopy. We propose that proteasome particles may disintegrate when prepared for electron microscopy by methods such as the two-step stain protocol and that prosome particles represent the component parts of the proteasome. Furthermore, based on the enhancement of proteasome images obtained using the one-step main protocol we propose that, instead of consisting of a stack of four rings, the proteasome is constructed of three components, i.e., a spherical central particle flanked by two flat hexagonal end caps.

Sequential up-regulation of thyroid hormone beta receptor, ornithine transcarbamylase, and carbamyl phosphate synthetase mRNAs in the liver of Rana catesbeiana tadpoles during spontaneous and thyroid hormone-induced metamorphosis.

During both spontaneous and thyroid hormone (TH)-induced metamorphosis, the Rana catesbeiana tadpole undergoes postembryonic developmental changes in its liver which are necessary for its transition from an ammonotelic larva to a ureotelic adult. Although this transition ultimately results from marked increases in the activities and/or de novo synthesis of the urea cycle enzymes, the precise molecular means by which TH exerts this tissue-specific response are presently unknown. Recent reports, using RNA from whole Xenopus laevis tadpole homogenates and indirect means of measuring TH receptor (TR) mRNAs, suggest a correlation between the up-regulation of TR beta-mRNAs and the general morphological changes occurring during amphibian metamorphosis. To assess whether or not this same relationship exists in a TH-responsive tissue, such as liver, we isolated and characterized a cDNA clone containing the complete nucleotide sequence for a R. catesbeiana urea cycle enzyme, ornithine transcarbamylase (OTC), as well as a genomic clone containing a portion of the hormone-binding domain of a R. catesbeiana TR beta gene. Through use of these homologous sequences and a heterologous cDNA fragment encoding rat carbamyl phosphate synthetase (CPS), we directly determined the relative levels of the TR beta, OTC, and CPS mRNAs in liver from spontaneous and TH-induced tadpoles. Our results establish that TH affects an up-regulation of mRNAs for its own receptor prior to up-regulating CPS and OTC mRNAs. Moreover, results with cultured tadpole liver demonstrate that TH, in the absence of any other hormonal influence, can affect an up-regulation of both the TR beta and OTC mRNAs.

Inducible isoform of HSP70 is constitutively expressed in a muscle fiber type specific pattern.

The most prominent group of stress or heat-shock proteins (HSPs) has an Mr of approximately 70,000 and is collectively referred to as the HSP70 family. The extent of stress inducibility and subcellular location of the various HSP70 isoforms differ, but all appear to be involved with ATP-dependent stabilization or solubilization of proteins. One isoform, termed the inducible isoform of HSP70 (HSP72i), is normally absent in unstressed cells. In a previous study, we detected a protein corresponding in Mr and pI to HSP72i in unstressed rat muscle. Therefore, it was of interest to determine if this expression in unstressed muscle cells is general or confined to specific muscle fiber types. To answer this question we have employed various rat hindlimb muscles that differ in fiber type proportion from predominantly type I (soleus) to predominantly type IIB (white gastrocnemius). Proteins from muscle homogenates were separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, blotted to a nylon membrane, probed with a monoclonal antibody for HSP72i, and visualized using an alkaline phosphatase-conjugated secondary antibody. Immunoblot analyses demonstrate the constitutive expression of HSP72i in rat muscles comprised primarily of type I muscle fibers (soleus), but not in muscles comprised primarily of type IIB fibers (white gastrocnemius). In muscles of mixed fiber type, HSP72i content is roughly proportional to the percentage of type I fibers. These results substantiate that unstressed rat muscles express the inducible HSP72 isoform and demonstrate that its constitutive expression is proportional to the type I muscle fiber composition.

Expression of the proto-oncogene c-fos following electrical kindling in the rat.

Kindling is a permanent form of brain change that results from repeated elicitation of epileptiform neural activity. c-fos has been proposed as the gene responsible for turning on molecular events that might underlie the long-term neural changes that occur during kindling. This study investigated the enhancement of c-fos levels following kindled seizures and the role of c-fos in the plastic changes underlying kindling. Male hooded rats were electrically kindled in the amygdala and the resulting c-fos and c-Ha-ras gene expression was quantified using Northern blot hybridization analysis. The results indicated that c-fos was constitutively expressed in forebrain and cerebellum, and that basal levels of c-fos were equivalent in naive and in fully kindled rats that have been seizure-free for 3 weeks. Following an amygdala-piriform kindled seizure there was a massive and transient increase in c-fos levels throughout forebrain and cerebellum. Although enhanced c-fos levels were correlated with afterdischarge (AD) duration in the kindled site, enhanced c-fos levels were also observed in the amygdala-piriform contralateral to the kindled site, and the enhancement did not depend on the occurrence of AD in the contralateral amygdala-piriform. Furthermore, electrical stimulations not resulting in AD as well as other forms of control stimulation also increased c-fos levels. We conclude that c-fos was expressed simply as a consequence of neural activity and not exclusively due to the specific neural activity or underlying plastic change required for kindling. This does not preclude a role for c-fos in the long-term response to external stimuli, but it does suggest that c-fos is not the crucial 'master switch' in turning on a molecular program that might underlie kindling.

Sequence, identification and characterization of cDNAs encoding two different members of the 18 kDa heat shock family of Zea mays L.

Heat-shocked maize seedlings (cv. Oh43) synthesize a characteristic set of heat-shock proteins (hsps) which include an 18 kDa family containing at least six major isoelectric variants. A cDNA library was constructed from poly(A)+ RNAs isolated from the radicles of heat-shocked maize seedlings and screened with a DNA fragment from the theoretical open reading frame of a putative Black Mexican Sweet maize hsp18 genomic clone. Two clones, cMHSP18-3 and cMHSP18-9, were isolated, and the RNA transcripts generated from them were translated into proteins which immunoreact with antibodies directed against the maize 18 kDa hsps and exhibit the same electrophoretic characteristics as two different members of the 18 kDa hsp family. Nucleotide sequence analyses of the cDNAs in these clones reveal that their 5' and 3' untranslated regions exhibit 33-34% identity and that their protein encoding regions share 93% identity. The deduced amino acid sequences of these clones show 90% identity, and the apparent molecular masses and isoelectric points of these proteins agree with those established for two different 18 kDa hsps, numbered 3 and 6. This report substantiates that at least two of the 18 kDa hsps in maize are products of different but related genes. Moreover, it establishes that transcripts for these proteins accumulate during heat shock and that both their nucleotide and deduced amino acid sequences share extensive similarities with the class VI small hsps in soybean and with transcripts expressed during meiosis in Lilium.