Cardiac gene expression and systemic cytokine profile are complementary in a murine model of post-ischemic heart failure

After myocardial infarction (MI), activation of the immune system and inflammatory mechanisms, among others, can lead to ventricular remodeling and heart failure (HF). The interaction between these systemic alterations and corresponding changes in the heart has not been extensively examined in the setting of chronic ischemia. The main purpose of this study was to investigate alterations in cardiac gene and systemic cytokine profile in mice with post-ischemic HF. Plasma was tested for IgM and IgG anti-heart reactive repertoire and inflammatory cytokines. Heart samples were assayed for gene expression by analyzing hybridization to AECOM 32k mouse microarrays. Ischemic HF significantly increased the levels of total serum IgM (by 5.2-fold) and total IgG (by 3.6-fold) associated with a relatively high content of anti-heart specificity. A comparable increase was observed in the levels of circulating pro-inflammatory cytokines such as IL-1â (3.8X) and TNF-á (6.0X). IFN-ã was also increased by 3.1-fold in the MI group. However, IL-4 and IL-10 were not significantly different between the MI and sham-operated groups. Chemokines such as MCP-1 and IL-8 were 1.4- and 13-fold increased, respectively, in the plasma of infarcted mice. We identified 2079 well annotated unigenes that were significantly regulated by post-ischemic HF. Complement activation and immune response were among the most up-regulated processes. Interestingly, 21 of the 101 quantified unigenes involved in the inflammatory response were significantly up-regulated and none were down-regulated. These data indicate that post-ischemic heart remodeling is accompanied by immune-mediated mechanisms that act both systemically and locally.

Gap junctions in the cardiovascular and immune systems

Gap junctions are clusters of intercellular channels directly connecting the cytoplasm of adjacent cells. These channels are formed by proteins named connexins and are present in all metazoan organisms where they serve diverse functions ranging from control of cell growth and differentiation to electric conduction in excitable tissues. In this overview we describe the presence of connexins in the cardiovascular and lympho-hematopoietic systems giving the reader a summary of the topics to be covered throughout this edition and a historical perspective of the discovery of gap junctions in the immune system

A simple RT-PCR-based strategy for screening connexin identity

Vertebrate gap junctions are aggregates of transmembrane channels which are composed of connexin (Cx) proteins encoded by at least fourteen distinct genes in mammals. Since the same Cx type can be expressed in different tissues and more than one Cx type can be expressed by the same cell, the thorough identification of which connexin is in which cell type and how connexin expression changes after experimental manipulation has become quite laborious. Here we describe an efficient, rapid and simple method by which connexin type(s) can be identified in mammalian tissue and cultured cells using endonuclease cleavage of RT-PCR products generated from "multi primers" (sense primer, degenerate oligonucleotide corresponding to a region of the first extracellular domain; antisense primer, degenerate oligonucleotide complementary to the second extracellular domain) that amplify the cytoplasmic loop regions of all known connexins except Cx36. In addition, we provide sequence information on RT-PCR primers used in our laboratory to screen individual connexins and predictions of extension of the "multi primer" method to several human connexins

Biophysical properties of the human cardiac gap junction channel

1. Gap junction channels interconnect cells of the pacemaking, conduction and contraction elements of the heart and also endothelial and smooth muscle cells of vasculature, thereby providing pathways for electrotonic current spread and for second messenger diffusion. The major gap junction protein in the cardiovascular system is connexin43. 2. When human connexin43 is stably expressed in pairs of a communication-deficient cell line (SKHep1) channels are produced with unitary conductance (gamma j), lipophile sensitivity and voltage-dependent gating similar to those of mammalian systems in which connexin43 is endogenously expressed. 3. At moderate transjunctional voltages (Vj), two gamma j values dominated the recordings, about 60 and 90 pS with CsCl patch solution. The smaller channel size is favored by phosphorylating treatments and the larger channel, by dephosphorylating treatments. 4. Human connexin43 mutants truncated at the carboxy termini display a change in gamma j while a point mutation in the third transmembrane spanning domain appears to change channel selectivity. 5. Voltage dependence of the human connexin43 channel is marked at Vjs, above +/- 50 mV, but large residual conductance remains (due probably to a voltage-insensitive substate) even at the largest Vj values; kinetic but not steady-state behavior is affected by phosphorylation state

Properties of channels from rat liver gap junction membrane fractions incorporated into planar lipid bilayers

Rat membrane fractions highly enriched for gap junctions can be incorporated into planar lipid bilayers exhibiting channel currents with both voltage-dependent and independent components. Voltage dependence, however, is only one of the characteristics of liver gap junction channels. Other features include poor ionic selectivity and sensitivity to calcium, pH, octanol and to some intracellularly applied antibodies. To further test the junctional nature of channels from membrane fractions highly enriched in gap junctions incorporated into lipid bilayers we studied the sensitivity of these channels to uncoupling agents and determined channel selectivity properties. We found the incorporated channels to be insensitive to calcium and octanol, and in most cases to pH in the range of 5-7, suggesting that either these agents do not interact directly with the junctional channels or that the corresponding gating regions are inactivated during the isolation and reconstitution procedures. Attempts to block channel activity using polyclonal and monoclonal connexin 32 antibodies were generally unsuccessful, although one antibody (a monoclonal directed against the carboxy terminus portion of connexin32) blocked channel activity. Selectivity measurements indicated that the incorporated channels were slightly cation selective (PNa=Pk > PCl) and were permeable to large ions. These results further support the idea that functional connexin32 gap junction channels are present in channel activity recorded from rat liver junctional membranes incorporated into planar bilayers

Complex channel activity recorded from rat liver GAP junctional membranes incorporated into lipid bilayers

Channels from isolated liver junctional membranes were incorporated into lipid bilayers and studied under voltage clamp conditions. Detergent treatment of junctional membrane fragments greatly increased the incidence of channel incorporation but did not noticeably alter the properties of the incorporated channels. Incorporation resulted in channel activity displaying an approximately symmetric voltage dependence in which conductance was decrease with imposed transmembrane voltage exceeding ñ 20 mV. A residual coltage-independent conductance was also detected in membranes in which liver junctional membranes were incorporated. The magnitude of this voltage-insensitive component varied from less than 20% to more than 75% of the total conductance. These results are generally similar to those described by Young, Chn and Gilula(Cell, 48:733-743, 1987) in incorporation experiments following detergent treatment of isolated gap junction membranes. However, we interpret these data as indicating the existence of distint channel populations in the incorporated membrane fractions. Our results suggest that a population of larger conductance channels (* 150 pS) contributes the voltage-dependent component of the membrane conductance, while smailler channels (unitary conductance abouth 50-150 pS) contribute the voltage-independent component. The biophysical proprieties of the larger channel are comparable to those seen in communication-deficient cells transfected with connexin32, confirming a report describing conductance of bilayers in which electroeluted 27-kDa liver gap junction protein was inserted. These findings indicate that connexin32 comprises the larger, voltage-dependent channels seen in the bilayer experiments in which liver junctional membranes are incorporated