PsbI affects the stability, function, and phosphorylation patterns of photosystem II assemblies in tobacco

Photosystem II (PSII) core complexes consist of CP47, CP43, D1, D2 proteins and of several low molecular weight integral membrane polypeptides, such as the chloroplast-encoded PsbE, PsbF, and PsbI proteins. To elucidate the function of PsbI in the photosynthetic process as well as in the biogenesis of PSII in higher plants, we generated homoplastomic knock-out plants by replacing most of the tobacco psbI gene with a spectinomycin resistance cartridge. Mutant plants are photoautotrophically viable under green house conditions but sensitive to high light irradiation. Antenna proteins of PSII accumulate to normal amounts, but levels of the PSII core complex are reduced by 50%. Bioenergetic and fluorescence studies uncovered that PsbI is required for the stability but not for the assembly of dimeric PSII and supercomplexes consisting of PSII and the outer antenna (PSII-LHCII). Thermoluminescence emission bands indicate that the presence of PsbI is required for assembly of a fully functional Q(A) binding site. We show that phosphorylation of the reaction center proteins D1 and D2 is light and redox-regulated in the wild type, but phosphorylation is abolished in the mutant, presumably due to structural alterations of PSII when PsbI is deficient. Unlike wild type, phosphorylation of LHCII is strongly increased in the dark due to accumulation of reduced plastoquinone, whereas even upon state II light phosphorylation is decreased in delta psbI. These data attest that phosphorylation of D1/D2, CP43, and LHCII is regulated differently.     

Coupling between neuronal firing rate, gamma LFP, and BOLD fMRI is related to interneuronal correlations

BACKGROUND: To what extent is activity of individual neurons coupled to the local field potential (LFP) and to blood-oxygenation-level dependent (BOLD) functional magnetic resonance imaging (fMRI)? This issue is of high significance for understanding brain function and for relating animal studies to fMRI, yet it is still under debate. RESULTS: Here we report data from simultaneous recordings of isolated unit activity and LFP by using multiple electrodes in the human auditory cortex. We found a wide range of coupling levels between the activity of individual neurons and gamma LFP. However, this large variability could be predominantly explained (r = 0.66) by the degree of firing-rate correlations between neighboring neurons. Importantly, this phenomenon occurred during both sensory stimulation and spontaneous activity. Concerning the coupling of neuronal activity to BOLD fMRI, we found that gamma LFP was well coupled to BOLD measured across different individuals (r = 0.62). By contrast, the coupling of single units to BOLD was highly variable and, again, tightly related to interneuronal-firing-rate correlations (r = 0.70). CONCLUSIONS: Our results offer a resolution to a central controversy regarding the coupling between neurons, LFP, and BOLD signals by demonstrating, for the first time, that the coupling of single units to the other measures is variable yet it is tightly related to the degree of interneuronal correlations in the human auditory cortex.     

Caenorhabditis elegans glutamate transporter deletion induces AMPA-receptor/adenylyl cyclase 9-dependent excitotoxicity

In stroke and several neurodegenerative diseases, malfunction of glutamate (Glu) transporters causes Glu accumulation and triggers excitotoxicity. Many details on the cascade of events in the neurodegenerative process remain unclear. As molecular components of glutamatergic synapses are assembled in Caenorhabditis elegans and as many fundamental cellular processes are conserved from nematodes to humans, we studied Glu-induced necrosis in C. elegans and probed its genetic requirements. We combined Δglt-3 , a Glu transporter-null mutation, with expression of a constitutively active form of the alpha subunit of the G protein Gs. While neither Δglt-3 nor expression of the constitutively active form of the alpha subunit of the G protein Gs is severely toxic to C. elegans head interneurons, their combination induces extensive neurodegeneration. Δglt-3 -dependent neurodegeneration acts through Ca²⁺-permeable Glu receptors of the α-amino-3-hydroxyl-5-methyl-4-isoxazolepropionic acid (AMPA) subtype, requires calreticulin function, and is modulated by calcineurin and type-9 adenylyl cyclase (AC9). We further show that mammalian AC9 hyperactivates mammalian AMPA-receptors (AMPA-Rs) in a Xenopus oocyte expression system, supporting that the relationship between AMPA-Rs hyperactivation and AC9 might be conserved between nematodes and mammals. AMPA-Rs–AC9 synergism is thus critical for nematode excitotoxicity and could potentially be involved in some forms of mammalian neurodegeneration.     

A specific defect of prosolin phosphorylation in T cell leukemic lymphoblasts is associated with impaired down-regulation of DNA synthesis

Prosolin is a major cytosolic phosphoprotein of proliferating normal PBL. Treatment of growing PBL with phorbol ester (12-O-tetradecanoylphorbol-13-acetate (TPA)) or calcium ionophore (A23187) for 1 h caused phosphorylation of prosolin with the production of up to four prominent phosphorylated forms differing in degree of phosphorylation and/or two-dimensional electrophoretic mobility (peptides B to E). Formation of these phosphopeptides coincided with rapid down-regulation of DNA synthesis. A23187 was particularly effective in inducing phosphorylation of the more highly phosphorylated peptides D and E, suggesting the existence of a (Ca2+)-activated mechanism in their phosphorylation. The T cell leukemia cell lines Jurkat, HuT-78, CCRF-CEM, and Molt-4 showed reduced to absent ability to phosphorylate prosolin peptides rapidly in response to A23187 and also showed diminished down-regulation of DNA synthesis. In leukemic cells treated with both TPA and A23187, peptides B and C were rapidly phosphorylated, but the phosphorylation of peptides D and E seen in normal PBL remained deficient. The T cell leukemic cells appear to have intact a TPA-activated mechanism for phosphorylating prosolin peptides B and C, but share an impairment of a specific Ca2(+)-activated mechanism, possibly a Ca2(+)-dependent protein kinase, required for phosphorylation of prosolin phosphopeptides D and E. The degree of rapid down-regulation of DNA synthesis was correlated with degree of phosphorylation of peptide E in PBL and in three of four T cell leukemic cell lines. Thus, rapid phosphorylation of prosolin may mediate responses to TPA and A23187 in normal proliferating PBL, including down-regulation of DNA synthesis. A deficiency of this pathway in leukemic T cells may impede their response to physiologic growth regulatory signals utilizing this pathway and contribute to unrestrained cell growth.     

Keyhole limpet hemocyanin contains Gal(β1–3)-GalNAc determinants that are cross-reactive with the T antigen

Keyhole limpet hemocyanin (KLH) is widely used as a carrier molecule to enhance immune responses to administered antigens, and for immunotherapy of bladder and renal carcinoma. In the present study we show, using lectin and antibody binding studies, that native KLH contains Gal(1–3)GalNAc-bearing oligosaccharides, and that immunization with KLH in Lewis rats induces the production of anti-Gal(1–3)GalNAc antibodies. This might explain the beneficial effect of KLH in bladder cancers that express crossreactive Gal(1–3)GalNAc determinants or the T antigen.Supported by NIH grant NS11766 and by the William Rosenwald Family Fund Inc.     

The erythrocyte membranes in β-thalassemia. Lower sialic acid levels in glycophorin

The sialic acids content of glycophorin of thalassemic erythrocyte membranes is about 25% lower than in glycophorin of normal erythrocyte membranes. Glycophorin extracted from old thalassemic erythrocytes separated by density centrifugation, has about half the sialic acids content found in glycophorin extracted from young thalassemic erythrocytes. Possible sialidase activity was sought in the plasma and erythrocyte membranes of thalassemic erythrocytes. No increased sialidase activity was detected in the plasma of the patients as compared to that of normal donors. Thus, other sites for sialidase activity, or other possibilities have to be explored to account for the increased sialic acid hydrolysis of glycophorin of the thalassemic erythrocytes.     

Specificity of energy transfer to photosystem II by in vitro reassociated homologous and heterologous membrane-bound phycobilisomes

In a previous publication we have reported the in vitro reassociation of phycobiliproteins with thylakoids of Fremyella diplosiphon to form homologous, functional, membrane-bound phycobilisomes (Kirilovsky, D., Kessel, M. and Ohad, I (1983) Biochim. Biophys. Acta 724, 416–426). In the present work, using the same experimental system, we demonstrate the in vitro formation of heterologous, membrane-bound phycobilisomes. Analysis of phycobiliprotein association and binding curves disclosed two types of binding sites: specific sites which allow energy transfer to Photosystem II and non-specific sites which become occupied only after saturation of the Photosystem II specific sites. Binding to non-specific sites does not result in energy transfer. Both types of sites are present on cyanophyte thylakoids. Thylakoids of eukaryotic chloroplasts such as those of Chlamydomonas reinhardtii or Euglena gracilis can bind phycobiliproteins which reassociate to form intact membrane-bound phycobilisomes. However, only non-specific binding occurs in such heterologous systems. Limited proteolysis of membrane-bound phycobilisomes results in a rapid loss of the 94–95 kDa polypeptide assumed to be required for binding and energy transfer (Redlinger, T. and Gantt, E. (1982) Proc. Natl. Acad. Sci. USA 79, 5542–5546). Phycobilisomes lacking this polypeptide cannot bind to either specific or non-specific sites. Based on these results, we conclude that the 94–95 kDa polypeptide is required for the association of the phycobilisomes to both homologous and heterologous membranes; however, additional factors within the Photosystem II unit of cyanophytes are also required for establishing energy transfer.     

Metaproteome plasticity sheds light on the ecology of the rumen microbiome and its connection to host traits

The arsenal of genes that microbes express reflect the way in which they sense their environment. We have previously reported that the rumen microbiome composition and its coding capacity are different in animals having distinct feed efficiency states, even when fed an identical diet. Here, we reveal that many microbial populations belonging to the bacteria and archaea domains show divergent proteome production in function of the feed efficiency state. Thus, proteomic data serve as a strong indicator of host feed efficiency state phenotype, overpowering predictions based on genomic and taxonomic information. We highlight protein production of specific phylogenies associated with each of the feed efficiency states. We also find remarkable plasticity of the proteome both in the individual population and at the community level, driven by niche partitioning and competition. These mechanisms result in protein production patterns that exhibit functional redundancy and checkerboard distribution that are tightly linked to the host feed efficiency phenotype. By linking microbial protein production and the ecological mechanisms that act within the microbiome feed efficiency states, our present work reveals a layer of complexity that bears immense importance to the current global challenges of food security and sustainability.Subject terms: Microbial ecology, Microbiome