The plasma membrane of Entamoeba histolytica: structure and dynamics.

The plasma membrane components of the parasitic protozoan Entamoeba histolytica, the causative agent of human invasive amebiasis, have been biochemically and immunologically characterized during the last decade. In addition, genes coding for certain surface proteins have been cloned. In spite of these advances, a unified characterization of plasma membrane antigenic components of the parasite is still required for badly needed advancements in the design of useful diagnostic, epidemiologic, and immunoprophylactic tools. Here we review current knowledge on this issue and address the problem of the considerable variation in the electrophoretic profiles of plasma membrane proteins obtained by different groups. In addition, the differences in the degree of recognition of reported membrane antigens with human immune sera, and the diverse interpretations concerning the possible functions of the surface molecules characterized are discussed. A comparative analysis of plasma membrane proteins of E histolytica trophozoites using three different isolation methods revealed that it is possible to select for specific membrane proteins, depending on the lysis conditions. In our view, the method of Calderón and Avila preserves more proteins than other methods tested. Using sera from recent cases of invasive amebiasis studied by several laboratories in various geographical areas, a basic antigenic pattern of 11 principal proteins with molecular weights of 220, 170, 150, 125, 97, 80, 60, 45, 20 and 9 kDA was established for the pathogenic E histolytica strain HM1:IMSS, used by most research groups.     

Contractile proteins in podocytes: immunocytochemical localization of actin and alpha-actinin in normal and nephrotic rat kidneys

Actin and alpha-actinin immunoreactive sites have been localized at the electron microscope level by the protein A-gold immunocytochemical technique in podocytes of normal and nephrotic rat renal tissues. In normal renal glomeruli, fibrillar networks located in the core of foot processes or bundles of micro filaments interconnecting them were found to be labelled for these two cytoskeletal proteins. On the other hand, in nephrotic renal glomeruli, concomitant with the loss of podocytic foot processes a reorganization of the podocytic cytoskeleton and a concentration of some of its elements into thick uniform bands was observed. Actin and alpha-actinin were revealed in these bands. Control experiments confirmed the specificity of the labelling obtained. Our results suggest that normal podocytes contain an actin-based contractile system that might contribute to the maintenance of the particular cell shape of these cells and that the rearrangement of the podocytic cyto-skeleton occurring in the nephrotic syndrome might account for the changes in the foot processes and contribute to the alteration in glomerular function. This work was supported by grants from the Medical Research Council of Canada     

Evolutionary aspects of trypanosomes: Analysis of genes

Summary The genes for four glycolytic enzymes ofTrypanosoma brucei have been analyzed. The proteins encoded by these genes show 38–57% identity with their counterparts in other organisms, whether pro- or eukaryotic. These data are consistent with a phylogenetic tree in which trypanosomes diverged very early from the main branch of the eukaryotic lineage. No definite conclusion can be drawn yet about the evolutionary origin of glycosomes, the microbodies of trypanosomes which contain most enzymes of the glycolytic pathway. A bias could be observed in the codon usage of the glycolytic genes and genes for other housekeeping proteins, indicating that trypanosomes may have selected a nucleotide sequence that enables efficient translation. However, the genes for variant surface glycoproteins (VSGs) do not show such a bias. This lack of preference for special codons is explained by the high evolutionary rate that could be observed for VSG genes.Presented at the FEBS Symposium on Genome Organization and Evolution, held in Crete, Greece, September 1–5, 1986     

Microheterogeneity of Micro tubule-Associated τ Proteins Is Due to Differences in Phosphorylation

We have studied the heterogeneity of the microtubule-associated tau proteins using tau-specific antibodies and two-dimensional electrophoresis. Both monoclonal and polyclonal antibodies to tau proteins recognize five bands in cow brain microtubule proteins run on sodium dodecyl sulfate (SDS)-polyacrylamide gels, with apparent molecular weights between 56,000 and 66,000. Immunoblots of cow brain microtubules separated on two-dimensional gels, using nonequilibrium pH gradient electrophoresis in the first dimension and SDS-gel electrophoresis in the second, reveal that greater than 30 isoforms of tau exist. The tau proteins vary in pI from 6.5 to 8.5, with the higher-molecular-weight forms being more acidic. The microheterogeneity of tau is not induced by cycling of microtubules, because two-dimensional immunoblots of tau from total brain are almost identical to those of tau from cycled tubules. Adult rat brain tau, which appears as three doublet bands on SDS gels, also exhibits considerable isoelectric heterogeneity, as does tau from 7-day-old rats, which appears as only one band on SDS gels. After dephosphorylation of cow brain tau with alkaline phosphatase, the highest-molecular-weight band disappears on SDS gels. On two-dimensional gels, the number of tau variants decreases by more than half after dephosphorylation, and the more basic species increase greatly in intensity. Preliminary experiments with tau labeled in vivo with 32PO4 also indicate that the more acidic tau proteins are the more highly phosphorylated forms. Thus, isoelectric heterogeneity of tau proteins exists at all ages and is due, at least in part to differences in the state of phosphorylation of tau isoforms.     

Expression of Microtubule-Associated Proteins During the Early Stages of Neurite Extension by Brain Neurons Cultured in a Defined Medium

Immunoblotting analysis was used to identify the microtubule-associated proteins (MAPs) present in cultures of mouse brain neurons. Polyclonal antibodies were raised against the two main adult brain MAPs, i.e., MAP2 (300 kDa) and tau (60-70 kDa). Whatever the stage of the culture, which was performed in a defined medium (3 or 6 days), the anti-MAP2 serum detected several high-molecular-weight components (including MAP2) and an entity with 62-65 kDa. Anti-tau revealed essentially a major peak of 48 kDa (young tau) but also slightly cross-reacted with the 62-65 kDa entity. During the culture period (0-6 days) the cells developed progressively a dense neuritic network; the concentration of the different MAPs increased in parallel but at different rates depending on the different species. The increase in concentration of the high-molecular-weight components occurred before that of 48-kDa tau. This suggests that high-molecular-weight MAPs and 48-kDa tau might be involved respectively in the initiation and elongation of neurites. In contrast, and since the main developmental changes in tau composition seen in vivo did not occur during the time course of the culture, this transition might be related to later events of neuronal differentiation.     

Differential Degradation of Different Benzodiazepine Binding Proteins by Incubation of Membranes from Cerebellum or Hippocampus with Trypsin

When rat brain membranes were incubated with [3H]flunitrazepam in the presence of UV light, predominantly one protein (P51) was irreversibly labeled in cerebellum and at least two proteins (P51 and P55) were labeled in hippocampus. On digestion of membranes with increasing concentrations of trypsin up to 40% of radioactivity irreversibly bound to proteins was removed from the membranes. In addition, P51 was nearly completely degraded to a peptide with apparent molecular weight 39,000 and this peptide was further degraded to a peptide with apparent molecular weight 25,000. In contrast, protein P55 was only partially degraded by trypsin and yielded two proteolytic peptides with apparent molecular weights 42,000 and 45,000 which seemed to be rather stable against further attack by trypsin. Membranes treated with trypsin still had the capacity to bind [3H]-flunitrazepam reversibly with an affinity similar to that of membranes not previously treated with trypsin. When these membranes were irradiated with UV light, the same proteolytic peptides were detected as in membranes first photolabeled and then digested with trypsin. These results suggest a close association between reversible and irreversible benzodiazepine binding sites and indicate that membrane-associated proteins P51 and P55 are differentially protected against degradation by trypsin.     

Temporal Profiles of Proteins Responsive to Transient Ischemia

The responses of long and short half-lived proteins to ischemia were measured in rat brain during 6 days of recovery from 30 min of transient forebrain ischemia produced by four-vessel occlusion. At the end of the ischemic interval, the neocortical activities of four vulnerable enzymes [ornithine (ODC) and S-adenosylmethionine (SAMDC) decarboxylases, and RNA polymerases I and II] were unchanged, but within 30 min of reperfusion, their activities dropped by 25-50%. The loss of substance P in the striatum and substantia nigra was slower, reaching about 50% by 12 h. On the other hand, the activities of 5 long half-lived enzymes did not change in the neocortex at 5 and 15 h of reperfusion and regional protein concentrations were essentially unaffected over 6 days survival. The rate and extent of normalization of the amounts or activities of the vulnerable proteins varied. RNA polymerase II and ODC activities were restored within 4 h, and ODC showed a biphasic increase in activity, with peaks at 10 h and 2-3 days. RNA polymerase I and SAMDC activities were restored by 18 h and 5 days, respectively, whereas substance P concentrations did not completely recover, even at 6-15 days. The greater the regional reduction of blood flow during ischemia, the larger the net change (gain or loss) of SAMDC or ODC activity and the longer the time required to normalize the activities of these enzymes. The average rate of proteolysis, assessed by measuring the rate of clearance of 14C from protein prelabeled with [14C]bicarbonate, was abnormal during the first 2 days of reperfusion. Postischemic changes in both protein synthesis and degradation could affect the amounts of some of the proteins responsive to transient ischemia.     

An Immunoblot Study of Neurofilament Degradation In Situ and During Calcium-Activated Proteolysis

The degradation of neurofilament (NF) proteins was examined by immunoblot methods to identify, characterize, and monitor the appearance of immunoreactive breakdown products during the loss of NF triplet proteins. Individual NF proteins and their breakdown products were identified using polyclonal and monoclonal antibodies to NF proteins. NF degradation was compared during calcium-activated proteolysis of isolated rat NF, during an experimental influx of calcium into excised rat spinal nerve roots, and during NF breakdown in transected rat peripheral nerve. These different experimental conditions produced similar patterns of NF fragmentation, including the transient appearance of NF immunobands between Mr 150,000-200,000 and 110,000-120,000 as well as the appearance and accumulation of NF immunobands between Mr 45,000 and 65,000. Most immunoreactive NF fragments remained Triton-insoluble. Low levels of the same immunoreactive fragments were present in control neural tissues, suggesting that calcium-activated proteolysis may be operative in the turnover and/or processing of NF proteins in vivo. Very similar patterns of NF degradation during experimental calcium influxes into different CNS and PNS tissues are indicative of the widespread distribution of calcium-activated NF protease in neural tissues.     

Changes in Protein Content of Goldfish Optic Nerve During Degeneration and Regeneration Following Nerve Crush

Abstract: After the goldfish optic nerve was crushed, the total amount of protein in the nerve decreased by about 45% within 1 week as the axons degenerated, began to recover between 2 and 5 weeks as axonal regeneration occurred, and had returned to nearly normal by 12 weeks. Corresponding changes in the relative amounts of some individual proteins were investigated by separating the proteins by two-dimensional gel electrophoresis and performing a quantitative analysis of the Coomassie Brilliant Blue staining patterns of the gels. In addition, labelling patterns showing incorporation of [³H]proline into individual proteins were examined to differentiate between locally synthesized proteins (presumably produced mainly by the glial cells) and axonal proteins carried by fast or slow axonal transport. Some prominent nerve proteins, ON1 and ON2 (50–55 kD, pI ～6), decreased to almost undetectable levels and then reappeared with a time course corresponding to the changes in total protein content of the nerve. Similar changes were seen in a protein we have designated NF (～130 kD, pI ～5.2). These three proteins, which were labelled in association with slow axonal transport, may be neurofilament constituents. Large decreases following optic nerve crush were also seen in the relative amounts of α- and β-tubulin, which suggests that they are localized mainly in the optic axons rather than the glial cells. Another group of proteins, W2, W3, and W4 (35–45 kD, pI 6.5–7.0), which showed a somewhat slower time course of disappearance and were intensely labelled in the local synthesis pattern, may be associated with myelin. A small number of proteins increased in relative amount following nerve crush. These included some, P1 and P2 (35–40 kD, pIs 6.1–6.2) and NT (～50 kD, pI ～5.5), that appeared to be synthesized by the glial cells. Increases were also seen in one axonal protein, B (～45 kD, pI ～4.5), that is carried by fast axonal transport, as well as in two axonal proteins, HA1 and HA2 (～60 and 65 kD respectively, pIs 4.5–5.0), that are carried mainly by slow axonal transport. Other proteins, including actin, that showed no net changes in relative amount (but presumably changed in absolute amount in direct proportion to the changes in total protein content of the nerve), are apparently distributed in both the neuronal and nonneuronal compartments of the nerve.     

Ultrastructural localization of the calcium-binding protein parvalbumin in neurons of the song system of the zebra finch,Poephila guttata

Summary The distribution of parvalbumin (PV) within neurons of the vocal motor nucleus hyperstriatum ventralepars caudalis (HVc) was investigated in the forebrain of adult male zebra finches by means of light and electron microscopy using the indirect immunoperoxidase technique. Parvalbumin-reaction product was located in the amorphous material of perikarya, dendrites and nuclei, and associated to microtubuli, postsynaptic densities and intracellular membranes; it was found in some axons and Gray type-2 boutons, but rarely in type-1 boutons and never in the Golgi apparatus. These observations suggest that parvalbumin may regulate calcium-dependent processes at the postsynaptic membrane and in the cytosol. Furthermore, the partial association of parvalbumin to microtubuli points to an involvement in calcium-dependent tubular functions. Calcium currents and microtubular assembly or transport may be relevant for the known functions of HVc in song learning.