A novel mitochondrial septin-like protein, ARTS, mediates apoptosis dependent on its P-loop motif.

Here we describe a protein product of the human septin H5/PNUTL2/CDCrel2b gene, which we call ARTS (for apoptosis-related protein in the TGF-beta signalling pathway). ARTS is expressed in many cells and acts to enhance cell death induced by TGF-beta or, to a lesser extent, by other apoptotic agents. Unlike related septin gene products, ARTS is localized to mitochondria and translocates to the nucleus when apoptosis occurs. Mutation of the P-loop of ARTS abrogates its competence to activate caspase 3 and to induce apoptosis. Taken together, these observations expand the functional attributes of septins previously described as having roles in cytokinesis and cellular morphogenesis.

Manipulations of ACHE gene expression suggest non-catalytic involvement of acetylcholinesterase in the functioning of mammalian photoreceptors but not in retinal degeneration.

To explore role(s) of acetylcholinesterase (AChE) in functioning and diseased photoreceptors, we studied normal (rd/+) and degenerating (rd/rd) murine retinas. All retinal neurons, expressed AChEmRNA throughout fetal development. AChE and c-Fos mRNAs peaked at post-natal days 10-12, when apoptosis of rd/rd photoreceptors begins. Moreover, c-Fos and AChEmRNA were co-overexpressed in rd/rd mice producing transgenic human (h), and host (m) AChE, but not in rd/+ mice. However, mAChE overexpression also occurred in transgenics expressing human serum albumin. Drastic variations in AChE catalytic activity were ineffective during development. Neither transgenic excess nor diisopropylfluorophosphonate (DFP) inhibition (80%) affected the rd phenotype; nor did DFP exposure induce photoreceptor degeneration or affect other key cholinergic proteins in rd/+ mice, unlike reports of adult mice and despite massive induction under DFP of c-Fos70 years). Therefore, the extreme retinal sensitivity to AChE modulation may reflect non-catalytic function(s) of AChE in adult photoreceptors. These findings exclude AChE as causing the rd phenotype, suggest that its primary function(s) in mammalian retinal development are non-catalytic ones and indicate special role(s) for the AChE protein in adult photoreceptors.

Effect of truncated forms of the steroidogenic acute regulatory protein on intramitochondrial cholesterol transfer.

It has been proposed that the steroidogenic acute regulatory (StAR) protein controls hormone-stimulated steroid production by mediating cholesterol transfer to the mitochondrial inner membrane. This study was conducted to determine the effect of wild-type StAR and several modified forms of StAR on intramitochondrial cholesterol transfer. Forty-seven N-terminal or 28 C-terminal amino acids of the StAR protein were removed, and COS-1 cells were transfected with pCMV vector only, wild-type StAR, N-47, or the C-28 constructs. Lysates from the transfected COS-1 cells were then incubated with mitochondria from MA-10 mouse Leydig tumor cells that were preloaded with [3H]cholesterol. After incubation, mitochondria were collected and fractionated on sucrose gradients into outer membranes, inner membranes, and membrane contact sites, and [3H]cholesterol content was determined in each membrane fraction. Incubation of MA-10 mitochondria with wild-type StAR containing cell lysate resulted in a significant 34.9% increase in [3H]cholesterol content in contact sites and a significant 32.8% increase in inner mitochondrial membranes. Incubations with cell lysate containing N-47 StAR protein also resulted in a 16.4% increase in [3H]cholesterol in contact sites and a significant 26.1% increase in the inner membrane fraction. In contrast, incubation with the C-28 StAR protein had no effect on cholesterol transfer. The cholesterol-transferring activity of the N-47 truncation, in contrast to that of the C-28 mutant, was corroborated when COS-1 cells were cotransfected with F2 vector (containing cytochrome P450 side-chain cleavage enzyme, ferridoxin, and ferridoxin reductase) and either pCMV empty vector or the complementary DNAs of wild-type StAR, N-47 StAR, or C-28 StAR. Pregnenolone production was significantly increased in both wild-type and N-47-transfected cells, whereas that in C-28-transfected cells was similar to the control value. Finally, immunolocalization studies with confocal image and electron microscopy were performed to determine the cellular location of StAR and its truncated forms in transfected COS-1 cells. The results showed that wild-type and most of the C-28 StAR protein were imported into the mitochondria, whereas most of N-47 protein remained in the cytosol. These studies demonstrate a direct effect of StAR protein on cholesterol transfer to the inner mitochondrial membrane, that StAR need not enter the mitochondria to produce this transfer, and the importance of the C-terminus of StAR in this process.

Transgenic acetylcholinesterase induces enlargement of murine neuromuscular junctions but leaves spinal cord synapses intact.

Acetylcholinesterase (AChE) produced by spinal cord motoneurons accumulates within axo-dendritic spinal cord synapses. It is also secreted from motoneuron cell bodies, through their axons, into the region of neuromuscular junctions, where it terminates cholinergic neurotransmission. Here we show that transgenic mice expressing human AChE in their spinal cord motoneurons display primarily normal axo-dendritic spinal cord cholinergic synapses in spite of the clear excess of transgenic over host AChE within these synapses. This is in contrast to our recent observation that a modest excess of AChE drastically affects the structure and long-term functioning of neuromuscular junctions in these mice although they express human AChE in their spinal cord, but not muscle. Enlarged muscle endplates with either exaggerated or drastically shortened post-synaptic folds then lead to a progressive neuromotor decline and massive amyotrophy (Andres et al., 1997). These findings demonstrate that excess neuronal AChE may cause distinct effects on spinal cord and neuromuscular synapses and attribute the late-onset neuromotor deterioration observed in AChE transgenic mice to neuromuscular junction abnormalities.

Acetylcholinesterase enhances neurite growth and synapse development through alternative contributions of its hydrolytic capacity, core protein, and variable C termini.

Accumulated indirect evidence suggests nerve growth-promoting activities for acetylcholinesterase (AChE). To determine unequivocally whether such activities exist, whether they are related to the capacities of this enzyme to hydrolyze acetylcholine and enhance synapse development, and whether they are associated with alternative splicing variants of AChEmRNA, we used four recombinant human AChEDNA vectors. When Xenopus laevis embryos were injected with a vector expressing the synapse-characteristic human AChE-E6, which contains the exon 6-encoded C terminus, cultured spinal neurons expressing this enzyme grew threefold faster than co-cultured control neurons. Similar enhancement occurred in neurons expressing an insertion-inactivated human AChE-E6-IN protein, containing the same C terminus, and displaying indistinguishable immunochemical and electrophoretic migration properties from AChE-E6, but incapable of hydrolyzing acetylcholine. In contrast, the nonsynaptic secretory human AChE-I4, which contains the pseudointron 4-derived C terminus, did not affect neurite growth. Moreover, no growth promotion occurred in neurons expressing the catalytically active C-terminally truncated human AChE-E4, demonstrating a dominant role for the E6-derived C terminus in neurite extension. Also, AChE-E6 was the only active enzyme variant to be associated with Xenopus membranes. However, postsynaptic length measurements demonstrated that both AChE-E6 and AChE-E4 enhanced the development of neuromuscular junctions in vivo, unlike the catalytically inert AChE-E6-IN and the nonsynaptic AChE-I4. These findings demonstrate an evolutionarily conserved synaptogenic activity for AChE that depends on its hydrolytic capacity but not on its membrane association. Moreover, this synaptogenic effect differs from the growth-promoting activity of AChE, which is unrelated to its hydrolytic capacity yet depends on its exon 6-mediated membrane association.

Spatio-temporal expression patterns of steroidogenic acute regulatory protein (StAR) during follicular development in the rat ovary.

The steroidogenic acute regulatory protein (StAR) is a vital mitochondrial protein that is indispensable for the synthesis of steroid hormones in the steroidogenic cells of the adrenal cortex and the gonads. Recent studies have shown that StAR enhances the conversion of the substrate for all steroid hormones, cholesterol, into pregnenolone, probably by facilitating cholesterol entry into the inner compartment of the mitochondria where the steroidogenic cytochrome P450scc complex resides. To study the potential of StAR to affect ovarian steroidogenesis during follicular development, we examined the time-dependent expression of StAR protein and messenger RNA in PMSG/human CG (hCG)-treated immature rats. Western blot analyses and immunohistochemical and RT-PCR methodologies have revealed a biphasic expression of StAR in the ovaries responding to hormones. The first peak of StAR expression was generated by PMSG administration and lasted for 24 h. Furthermore, it was restricted to the entire network of the ovarian secondary interstitial tissue, as well as to a fewer scattered theca-interna cells. The second burst of StAR expression was observed in response to the LH surge, as simulated by hCG. This time, StAR was expressed in the entire theca-interna and interstitial tissue, as well as in those granulosa cells that were confined to periovulatory follicles. Immunoelectron microscopy studies revealed the over 90% of StAR antigenic sites are localized in the inner compartments of the mitochondrion, suggesting a rapid removal of StAR precursor from the mitochondrial surface, where it is believed to exert its activity. Altogether, our observations portray dynamic acute alterations of StAR expression during the process of follicular maturation in this animal model. Furthermore, if StAR indeed determines steroidogenic capacities in the ovary, our findings imply that, in immature rats undergoing hormonally induced first ovulation: 1) the early phases of follicular development are supported by androgen production originating from nonfollicular cells; 2) estrogen production in the granulosa cells of Graafian follicles is nourished by a submaximal androgenic output in the theca-interstitial compartments of the ovary.

Acetylcholinesterase-transgenic mice display embryonic modulations in spinal cord choline acetyltransferase and neurexin Ibeta gene expression followed by late-onset neuromotor deterioration.

To explore the possibility that overproduction of neuronal acetylcholinesterase (AChE) confers changes in both cholinergic and morphogenic intercellular interactions, we studied developmental responses to neuronal AChE overexpression in motoneurons and neuromuscular junctions of AChE-transgenic mice. Perikarya of spinal cord motoneurons were consistently enlarged from embryonic through adult stages in AChE-transgenic mice. Atypical motoneuron development was accompanied by premature enhancement in the embryonic spinal cord expression of choline acetyltransferase mRNA, encoding the acetylcholine-synthesizing enzyme choline acetyltransferase. In contrast, the mRNA encoding for neurexin-Ibeta, the heterophilic ligand of the AChE-homologous neuronal cell surface protein neuroligin, was drastically lower in embryonic transgenic spinal cord than in controls. Postnatal cessation of these dual transcriptional responses was followed by late-onset deterioration in neuromotor performance that was associated with gross aberrations in neuromuscular ultrastructure and with pronounced amyotrophy. These findings demonstrate embryonic feedback mechanisms to neuronal AChE overexpression that are attributable to both cholinergic and cell-cell interaction pathways, suggesting that embryonic neurexin Ibeta expression is concerted in vivo with AChE levels and indicating that postnatal changes in neuronal AChE-associated proteins may be involved in late-onset neuromotor pathologies.

Normal and atypical butyrylcholinesterases in placental development, function, and malfunction.

1. In utero exposure to poisons and drugs (e.g., anticholinesterases, cocaine) is frequently associated with spontaneous absorption and placental malfunction. The major protein interacting with these compounds is butyrylcholinesterase (BuChE), which attenuates the effects of such xenobiotics by their hydrolysis or sequestration. Therefore, we studied BuChE expression during placental development. 2. RT-PCR revealed both BuChEmRNA and acetylcholinesterase (AChE) mRNA throughout gestation. However, cytochemical staining detected primarily BuChE activity in first-trimester placenta but AChE activity in term placenta. 3. As the atypical variant of BuChE has a narrower specificity for substrates and inhibitors than the normal enzyme, we investigated its interactions with alpha-solanine and cocaine, and sought a correlation between the occurrence of this variant and placental malfunction. 4. Atypical BuChE of serum or recombinant origin presented > 10-fold weaker affinities than normal BuChE for cocaine and alpha-solanine. However, BuChE in the serum of the heterozygote and a homozygous normal were similar in their drug affinities. Therefore, heterozygous serum or placenta can protect the fetus from drug or poison exposure, unlike homozygous atypical serum or placenta. 5. Genotype analyses revealed that heterozygous carriers of atypical BuChE were threefold less frequent among 49 patients with placental malfunction than among 76 controls of the entire Israeli population. These observations exclude heterozygote carriers of atypical BuChE from being at high risk for placental malfunction under exposure to anticholinesterases.

Submitochondrial distribution of three key steroidogenic proteins (steroidogenic acute regulatory protein and cytochrome p450scc and 3beta-hydroxysteroid dehydrogenase isomerase enzymes) upon stimulation by intracellular calcium in adrenal glomerulosa cells.

In adrenal glomerulosa cells, angiotensin II (Ang II) and potassium stimulate aldosterone synthesis through activation of the calcium messenger system. The rate-limiting step in steroidogenesis is the transfer of cholesterol to the inner mitochondrial membrane. This transfer is believed to depend upon the presence of the steroidogenic acute regulatory (StAR) protein. The aim of this study was 1) to examine the effect of changes in cytosolic free calcium concentration and of Ang II on intramitochondrial cholesterol and 2) to study the distribution of StAR protein in submitochondrial fractions during activation by Ca2+ and Ang II. To this end, freshly prepared bovine zona glomerulosa cells were submitted to a high cytosolic Ca2+ clamp (600 nM) or stimulated with Ang II (10 nM) for 2 h. Mitochondria were isolated and subfractionated into outer membranes, inner membranes (IM), and contact sites (CS). Stimulation of intact cells with Ca2+ or Ang II led to a marked, cycloheximide-sensitive increase in cholesterol in CS (to 143 +/- 3. 2 and 151.1 +/- 18.1% of controls, respectively) and in IM (to 119 +/- 5.1 and 124.5 +/- 6.5% of controls, respectively). Western blot analysis revealed a cycloheximide-sensitive increase in StAR protein in mitochondrial extracts of Ca2+-clamped glomerulosa cells (to 159 +/- 23% of controls). In submitochondrial fractions, there was a selective accumulation of StAR protein in IM following stimulation with Ca2+ (228 +/- 50%). Similarly, Ang II increased StAR protein in IM, and this effect was prevented by cycloheximide. In contrast, neither Ca2+ nor Ang II had any effect on the submitochondrial distribution of cytochrome P450scc and 3beta-hydroxysteroid dehydrogenase isomerase. The intramitochondrial presence of the latter enzyme was further confirmed by immunogold staining in rat adrenal fasciculata cells and by immunoblot analysis in MA-10 mouse testicular Leydig cells. These findings demonstrate that under acute stimulation with Ca2+-mobilizing agents, newly synthesized StAR protein accumulates in IM after transiting through CS. Moreover, our results suggest that the import of StAR protein into IM may be associated with cholesterol transfer, thus promoting precursor supply to the two first enzymes of the steroidogenic cascade within the mitochondria and thereby activating mineralocorticoid synthesis.

Steroid production after in vitro transcription, translation, and mitochondrial processing of protein products of complementary deoxyribonucleic acid for steroidogenic acute regulatory protein.

We have previously demonstrated that steroidogenic acute regulatory protein (StAR) is essential for the rate-limiting step in the acute regulation of steroidogenesis, which is the transport of cholesterol from the outer to the inner mitochondrial membrane. We have hypothesized that this transport occurs as the 37-kilodalton (kDa) precursor form of StAR is imported into the mitochondria and processed to its 30-kDa mature forms. Using an in vitro transcription and translation system in the presence of mitochondria isolated from unstimulated mouse MA-10 Leydig tumor cells, we now directly show that the 37-kDa form is indeed the cytosolic precursor of StAR and can be processed by mitochondria to all four 30-kDa mature forms. To determine the subcellular location of StAR in steroidogenic cells, ultrastructural immunocytochemistry was performed in adrenal zona fasciculata cells using the protein A-gold technique. We show that StAR is associated exclusively with the mitochondria. There, StAR is primarily localized in the intermembrane space and the intermembrane space side of the cristae membrane. StAR was shown to induce steroid production in isolated mitochondria. StAR protein was expressed in COS1 cells and the cell lysate, which was shown to contain abundant levels of StAR by Western blot analysis, was incubated with mitochondria isolated from unstimulated MA-10 cells. In these experiments, StAR increased steroid production by at least 4-fold over control mock-transfected lysate, and this increase was time and dose dependent. Furthermore, the increase in steroid production induced by StAR-containing lysate was not observed when COS1 lysate containing high levels of another mitochondrially imported protein, adrenodoxin, was used. We conclude from these results that in response to tropic hormone stimulation of steroidogenic cells, StAR is synthesized as a 37-kDa precursor, imported into the mitochondria, processed to its 30-kDa mature forms, and localized to the intermembrane space. During import and processing in vitro, StAR induces steroid production in isolated mitochondria in a specific manner.

Transgenic expression of human acetylcholinesterase induces progressive cognitive deterioration in mice.

BACKGROUND: Cognitive deterioration is a characteristic symptom of Alzheimer's disease. This deterioration is notably associated with structural changes and subsequent cell death which occur, primarily, in acetylcholine-producing neurons, progressively damaging cholinergic neurotransmission. We have reported previously that excess acetylcholinesterase (AChE) alters structural features of neuromuscular junctions in transgenic Xenopus tadpoles. However, the potential of cholinergic imbalance to induce progressive decline of memory and learning in mammals has not been explored. RESULTS: To approach the molecular mechanisms underlying the progressive memory deficiencies associated with impaired cholinergic neurotransmission, we created transgenic mice that express human AChE in brain neurons. With enzyme levels up to two-fold higher than in control mice, transgenic mice displayed an age-independent resistance to the hypothermic effects of the AChE inhibitor, paraoxon. In addition to this improved scavenging capacity for anti-AChEs, however, these transgenic mice also resisted muscarinic, nicotinic and serotonergic agonists, indicating that secondary pharmacological changes had occurred. The transgenic mice also developed progressive learning and memory impairments, although their locomotor activities and open-field behaviour remained similar to those of matched control mice. By six months of age, transgenic mice lost their ability to respond to training in a spatial learning water maze test, whereas they performed normally in this test at the age of four weeks. This animal model is therefore suitable for investigating the transcriptional changes associated with cognitive deterioration and for testing drugs that may attenuate progressive damage. CONCLUSION: We conclude that upsetting cholinergic balance may by itself cause progressive memory decline in mammals, suggesting that congenital and/or acquired changes in this vulnerable balance may contribute to the physiopathology of Alzheimer's disease.

Synaptic and epidermal accumulations of human acetylcholinesterase are encoded by alternative 3'-terminal exons.

Tissue-specific heterogeneity among mammalian acetylcholinesterases (AChE) has been associated with 3' alternative splicing of the primary AChE gene transcript. We have previously demonstrated that human AChE DNA encoding the brain and muscle AChE form and bearing the 3' exon E6 (ACHE-E6) induces accumulation of catalytically active AChE in myotomes and neuromuscular junctions (NMJs) of 2- and 3-day-old Xenopus embryos. Here, we explore the possibility that the 3'-terminal exons of two alternative human AChE cDNA constructs include evolutionarily conserved tissue-recognizable elements. To this end, DNAs encoding alternative human AChE mRNAs were microinjected into cleaving embryos of Xenopus laevis. In contrast to the myotomal expression demonstrated by ACHE-E6, DNA carrying intron 14 and alternative exon E5 (ACHE-I4/E5) promoted punctuated staining of epidermal cells and secretion of AChE into the external medium. Moreover, ACHE-E6-injected embryos displayed enhanced NMJ development, whereas ACHE-I4/E5-derived enzyme was conspicuously absent from muscles and NMJs and its expression in embryos had no apparent effect on NMJ development. In addition, cell-associated AChE from embryos injected with ACHE-I4/E5 DNA was biochemically distinct from that encoded by the muscle-expressible ACHE-E6, displaying higher electrophoretic mobility and greater solubility in low-salt buffer. These findings suggest that alternative 3'-terminal exons dictate tissue-specific accumulation and a particular biological role(s) of AChE, associate the 3' exon E6 with NMJ development, and indicate the existence of a putative secretory AChE form derived from the alternative I4/E5 AChE mRNA.

Transgenic engineering of neuromuscular junctions in Xenopus laevis embryos transiently overexpressing key cholinergic proteins.

To examine the role of key cholinergic proteins in the formation of neuromuscular junctions (NMJs), we expressed DNAs encoding the mouse muscle nicotinic acetylcholine receptor (nAChR) or human brain and muscle acetylcholinesterase (hAChE) in developing Xenopus laevis embryos. Acetylthiocholine hydrolysis and alpha-bungarotoxin binding in homogenates of transgenic embryos revealed transient overexpression of the respective proteins for at least 4 days postfertilization. Moreover, hAChE injection induced an approximately 2-fold increase in endogenous Xenopus nAChR. Electron microscopy coupled with cytochemical staining for AChE activity revealed that AChE-stained areas, which reached 0.17 microns2 in NMJs of control embryos raised at 21 degrees C, increased up to 0.53 and 0.60 microns2 in nAChR and hAChE transgenics, respectively. These increases coincided with the appearance of a class of large NMJs with average postsynaptic lengths up to 1.8-fold greater than controls. As much as 57% and 34% of the NMJs in animals transgenic for nAChR and hAChE, respectively, displayed AChE activity in nerve terminals in addition to muscle labeling, as compared with 10% nerve-labeled NMJs in control animals. Moreover, area, but not length values, were > 2-fold larger in hAChE-expressing NMJs labeled in their nerve terminals than in those labeled in muscle alone, reflecting a hAChE-induced increase in synaptic cleft width. These findings indicate that modulation of cholinergic neurotransmission in NMJs modifies the features of nerve-muscle connections.

Overexpressed monomeric human acetylcholinesterase induces subtle ultrastructural modifications in developing neuromuscular junctions of Xenopus laevis embryos.

Formation of a functional neuromuscular junction (NMJ) involves the biosynthesis and transport of numerous muscle-specific proteins, among them the acetylcholine-hydrolyzing enzyme acetylcholinesterase (AChE). To study the mechanisms underlying this process, we have expressed DNA encoding human AChE downstream of the cytomegalovirus promoter in oocytes and developing embryos of Xenopus laevis. Recombinant human AChE (rHAChE) produced in Xenopus was biochemically and immunochemically indistinguishable from native human AChE but clearly distinguished from the endogenous frog enzyme. In microinjected embryos, high levels of catalytically active rHAChE induced a transient state of over-expression that persisted for at least 4 days postfertilization. rHAChE appeared exclusively as nonassembled monomers in embryos at times when endogenous Xenopus AChE displayed complex oligomeric assembly. Nonetheless, cell-associated rHAChE accumulated in myotomes of 2- and 3-day-old embryos within the same subcellular compartments as native Xenopus AChE. NMJs from 3-day-old DNA-injected embryos displayed fourfold or greater overexpression of AChE, a 30% increase in postsynaptic membrane length, and increased folding of the postsynaptic membrane. These findings indicate that an evolutionarily conserved property directs the intracellular trafficking and synaptic targeting of AChE in muscle and support a role for AChE in vertebrate synaptogenesis.

Expression of a human acetylcholinesterase promoter-reporter construct in developing neuromuscular junctions of Xenopus embryos.

We have employed Xenopus embryos to express human acetylcholinesterase (AcChoEase; EC 3.1.1.7) in developing synapses. Transcription of AcChoEase mRNA was driven by a 2.2-kb sequence upstream from the initiator AUG in the ACHE gene encoding AcChoEase, with multiple potential sites for binding universal and tissue-specific transcription factors. These included clustered MyoD elements, E-box, SP1, EGR1, AP-2, and the development-related GAGA motif. A DNA construct composed of this sequence linked to a 2.1-kb sequence encoding human AcChoEase was designated human AcChoEase promoter-reporter (HpACHE). HpACHE but none of its several 5'-truncated derivatives was transcriptionally active in developing Xenopus embryos. Furthermore, PCR analysis using chimeric PCR primers revealed usage of the same 1.5-kb intron and 74-bp exon within the HpACHE sequence in microinjected embryos and various human tissues. Cytochemical staining revealed conspicuous accumulation of overexpressed AcChoEase in neuromuscular junctions and within muscle fibers of apparently normal 2-day Xenopus embryos injected with HpACHE. The same reporter driven by the cytomegalovirus promoter was similarly efficient in directing the heterologous human enzyme toward neuromuscular junctions, attributing the evolutionary conservation of AcChoEase targeting to the coding sequence. Our findings demonstrate that a short DNA sequence is sufficient to promote the exogenous transcription and faithful splicing of human AcChoEase mRNA in developing Xenopus embryos and foreshadow their use for integrative studies of cholinergic signaling and synapse formation.

Thylakoid membrane energization and swelling in photoinhibited Chlamydomonas cells is prevented in mutants unable to perform cyclic electron flow.

Photoinhibition of Photosystem II in unicellular algae in vivo is accompanied by thylakoid membrane energization and generation of a relatively high ΔpH as demonstrated by (14)C-methylamine uptake in intact cells. Presence of ammonium ions in the medium causes extensive swelling of the thylakoid membranes in photoinhibited Chlamydomonas reinhardtii but not in Scenedesmus obliquus wild type and LF-1 mutant cells. The rise in ΔpH and the related thylakoid swelling do not occur at light intensities which do not induce photoinhibition. The rise in ΔpH and membrane energization are not induced by photoinhibitory light in C. reinhardtii mutant cells possessing an active Photosystem II but lacking cytochrome b6/f, plastocyanin or Photosystem I activity and thus being unable to perform cyclic electron flow around Photosystem I. In these mutants the light-induced turnover of the D1 protein of Reaction Center II is considerably reduced. The high light-dependent rise in ΔpH is induced in the LF-1 mutant of Scenedesmus which can not oxidize water but otherwise possesses an active Reaction Center II indicating that PS II-linear electron flow activity and reduction of plastoquinone are not required for this process. Based on these results we conclude that photoinhibition of Photosystem II activates cyclic electron flow around Photosystem I which is responsible for the high membrane energization and ΔpH rise in cells exposed to excessive light intensities.

Phorbol ester induces photoreceptor-specific degeneration in a Drosophila mutant.

In the retinal degeneration B (rdgB) mutant of Drosophila, the major class of photoreceptors degenerate when the fly is raised in the light for several days; raising the fly in the dark largely prevents the degeneration. Thus, the rdgB is a conditional mutant that requires the operation of some stages of the phototransduction cascade to express its characteristic phenotype. We report here experiments that examine the ability of chemical agents to mimic light by causing photoreceptor-specific degeneration in the dark. Application of a specific activator of protein kinase C, phorbol ester, to eyes of rdgB flies led to a degeneration of the photoreceptors that was indistinguishable from that caused by light: both light and phorbol ester-induced degeneration were characterized by (i) selective degeneration of one class of photoreceptors; (ii) a unique pattern of degeneration; and (iii) the appearance of light-induced regenerative spikes at early stages of degeneration. Application of phorbol ester to the eyes of wild-type flies had no effect. We suggest that light or phorbol ester activates a protein kinase C and results in a sustained or excessive phosphorylation of proteins in the rdgB mutant, leading to photoreceptor degeneration. Furthermore, the results are consistent with identification of the rdgB gene product as a phosphoprotein phosphatase that is nonfunctional or absent in the mutant.

Binding modes of IgG from pemphigus autoimmune sera onto guinea pig keratinocytes and the fate of bound IgGs.

Pemphigus is an intraepidermal autoimmune blistering disease of humans caused by circulating IgGs. We have investigated the binding mode and the fate of bound antibodies from Pemphigus sera (P-IgG) on guinea pig keratinocytes in suspension in order to find clues to the loss of cell adhesion in vivo (acantholysis). Flow cytometry, following indirect immunofluorescent labeling of the keratinocytes, and dead cells' staining with ethidium bromide, demonstrated the specific surface binding of P-IgG onto living keratinocytes only. This was shown with several Pemphigus sera or purified P-IgG. This technique, used with various Pemphigus sera, showed that the specific binding is increased when the serum titer is higher, and "Km" values for P-IgG were roughly and inversely correlated to the titers. Upon saturation the same average number of Pemphigus IgG sites per cell were found for the sera of different patients. Analysis of the specific binding of [125I]-P-IgG onto Percoll-separated (living) keratinocytes showed the existence of two classes of sites: 2 x 10(6) sites/cell high-affinity sites (Kd = 1.5 x 10(-6) M total IgG) and 25 x 10(6) sites/cell low-affinity sites (Kd = 6 x 10(-5) M total IgG). Cell sorting and flow cytometry of individual cells allowed us to correlate the light-scattering signal, the RNA content, the size and morphology, and the P-IgG binding to the cells. The results indicated that P-IgG binding is homogeneous within the living keratinocytes and increases with cell size (cell maturity). Cell-sorter analysis of cells with membrane-bound P-IgG, coupled to direct determination of P-IgG released in the medium, revealed the fate of bound P-IgG: 40-60% of the P-IgGs were released in the medium within 30 minutes at 37 degrees C. This was accompanied and followed by a much slower, metabolic energy-dependent, internalization process of the membrane-bound P-IgG. The internalization has been confirmed by electron microscopy of bound P-IgG labeled with protein A-gold. Internalized IgGs were seen in the cells in coated membranous vesicles and other endocytic compartments. Similar behavior was also observed with two other membrane ligands: i.e., concanavalin A and multispecific rabbit "antisurface" antibodies.

Turnover of thylakoid photosystem II proteins during photoinhibition of Chlamydomonas reinhardtii.

The turnover of photosystem-II proteins during photoinhibition was analyzed in the green alga Chlamydomonas reinhardtii. Changes in the amount of photosystem II core complex polypeptides D1, D2, 44 kDa and 51 kDa, the antennae-CP-29 and light-harvesting-complex-II polypeptides and the water-oxidizing complex polypeptides of 30 kDa, 23 kDa and 16 kDa were monitored by a variety of techniques. Only the D1 and D2 polypeptides were found to turnover during photoinhibition when cells were exposed to ten fold photosynthesis-saturating light (2500 W/m2 for 90 min) at 25 degrees C. While 80% of photosystem-II activity was lost, a reduction of only 20% was observed in the total amount of D1 and D2 proteins. However, inhibition of chloroplast translation by chloramphenicol during photoinhibition resulted in the loss of about 60% of the D1 and 40% of the D2 proteins, as demonstrated by Western blotting and dot blotting of isolated thylakoids, quantitative analysis of immunogold-labeled whole-cell thin sections, and chase of radioactively prelabelled proteins during photoinhibition. We propose that the light-dependent turnover of the D1 protein is a protective mechanism against photoinhibition as far as the removal and replacement of D1 is compatible with the photoinactivation incurred by photosystem II. At light intensities at which the rate of D1 removal becomes limiting, loss of photosystem-II activity exceeds the turnover of D1 and the stability of the D2 protein is impaired as well.

Preparation of antiserum to rat cytochrome P-450 cholesterol side chain cleavage, and its use for ultrastructural localization of the immunoreactive enzyme by protein A-gold technique.

Rabbit antiserum to rat cytochrome P-450 cholesterol side chain cleavage (P-450scc) was produced without a previous biochemical purification of the enzyme. Instead, for immunization we used a single protein band of mol wt 53,000, which was isolated from sodium dodecyl sulfate polyacrylamide gel electrophoresis of rat steroidogenic mitochondrial membranes. The resulting antiserum cross-reacted in a protein-blotting test with affinity purified and biologically active bovine adrenocortical P-450scc enzyme. The antiserum to the rat P-450scc also substantially blocked the conversion of cholesterol to pregnenolone in sonicated steroidogenic mitochondria, suggesting a successful cross-reactivity with the native form of the enzyme, despite the fact that the immunizing antigen was sodium dodecyl sulfate-denatured protein. The antiserum was applied for ultrastructural immunocytochemical visualization of the P-450scc in thin sections of adrenal cortex and immature ovary. Immunoreactive enzyme was identified by the protein-A-gold technique which showed that the gold particles concentrated exclusively in the steroidogenic mitochondria of adrenal zona glomerulosa and fasciculata cells. In the immature ovary, the only zone which was heavily stained with colloidal gold was the population of the interstitial cells. Part of the theca cell population contained P-450scc before PMSG treatment. The granulosa cells were devoided of the enzyme in any follicles before the preovulatory stage. The high resolution of the pAg technique allowed to visualize the localization of the P-450scc antigen in the matrix side of the inner mitochondrial membranes. Moreover, a clear coupling could be demonstrated between the morphological and functional maturation of the steroidogenic mitochondrion in the ovary: from a few lamella cristae devoid of P-450scc in the unstimulated granulosa mitochondria, to numerous tubulovesicular inner membranes, heavily loaded with the enzyme, in the mitochondria of the interstitial cells.