Hiding in plain sight: uncovering a new function of vitamin A in redox signaling.

The protein kinase Cδ signalosome modulates the generation of acetyl-Coenzyme A from glycolytic sources. This module is composed of four interlinked components: PKCδ, the signal adapter p66Shc, cytochrome c, and vitamin A. It resides in the intermembrane space of mitochondria, and is at the center of a feedback loop that senses upstream the redox balance between oxidized and reduced cytochrome c as a measure of the workload of the respiratory chain, and transmits a forward signal to the pyruvate dehydrogenase complex to adjust the flux of fuel entering the tricarboxylic acid cycle. The novel role of vitamin A as co-activator and potential electron carrier, required for redox activation of PKCδ, is discussed. This article is part of a Special Issue entitled Retinoid and Lipid Metabolism.

Regulation of intermediary metabolism by the PKCdelta signalosome in mitochondria.

PKCδ has emerged as a novel regulatory molecule of oxidative phosphorylation by targeting the pyruvate dehydrogenase complex (PDHC). We showed that activation of PKCδ leads to the dephosphorylation of pyruvate dehydrogenase kinase 2 (PDK2), thereby decreasing PDK2 activity and increasing PDH activity, accelerating oxygen consumption, and augmenting ATP synthesis. However, the molecular components that mediate PKCδ signaling in mitochondria have remained elusive so far. Here, we identify for the first time a functional complex, which includes cytochrome c as the upstream driver of PKCδ, and uses the adapter protein p66Shc as a platform with vitamin A (retinol) as a fourth partner. All four components are necessary for the activation of the PKCδ signal chain. Genetic ablation of any one of the three proteins, or retinol depletion, silences signaling. Furthermore, mutations that disrupt the interaction of cytochrome c with p66Shc, of p66Shc with PKCδ, or the deletion of the retinol-binding pocket on PKCδ, attenuate signaling. In cytochrome c-deficient cells, reintroduction of cytochrome c Fe(3+) protein restores PKCδ signaling. Taken together, these results indicate that oxidation of PKCδ is key to the activation of the pathway. The PKCδ/p66Shc/cytochrome c signalosome might have evolved to effect site-directed oxidation of zinc-finger structures of PKCδ, which harbor the activation centers and the vitamin A binding sites. Our findings define the molecular mechanisms underlying the signaling function of PKCδ in mitochondria.

Control of oxidative phosphorylation by vitamin A illuminates a fundamental role in mitochondrial energy homoeostasis.

The physiology of two metabolites of vitamin A is understood in substantial detail: retinaldehyde functions as the universal chromophore in the vertebrate and invertebrate eye; retinoic acid regulates a set of vertebrate transcription factors, the retinoic acid receptor superfamily. The third member of this retinoid triumvirate is retinol. While functioning as the precursor of retinaldehyde and retinoic acid, a growing body of evidence suggests a far more fundamental role for retinol in signal transduction. Here we show that retinol is essential for the metabolic fitness of mitochondria. When cells were deprived of retinol, respiration and ATP synthesis defaulted to basal levels. They recovered to significantly higher energy output as soon as retinol was restored to physiological concentration, without the need for metabolic conversion to other retinoids. Retinol emerged as an essential cofactor of protein kinase Cdelta (PKCdelta), without which this enzyme failed to be activated in mitochondria. Furthermore, retinol needed to physically bind PKCdelta, because mutation of the retinol binding site rendered PKCdelta unresponsive to Rol, while retaining responsiveness to phorbol ester. The PKCdelta/retinol complex signaled the pyruvate dehydrogenase complex for enhanced flux of pyruvate into the Krebs cycle. The baseline response was reduced in vitamin A-deficient lecithin:retinol acyl transferase-knockout mice, but this was corrected within 3 h by intraperitoneal injection of vitamin A; this suggests that vitamin A is physiologically important. These results illuminate a hitherto unsuspected role of vitamin A in mitochondrial bioenergetics of mammals, acting as a nutritional sensor. As such, retinol is of fundamental importance for energy homeostasis. The data provide a mechanistic explanation to the nearly 100-yr-old question of why vitamin A deficiency causes so many pathologies that are independent of retinoic acid action.

Embryonic chick corneal epithelium: a model system for exploring cell-matrix interactions.

In her initial research, Elizabeth D. Hay studied amphibian limb regeneration, but later switched her focus, and for the remainder of her career addressed the role of the extracellular matrix (ECM) in regulating embryonic morphogenesis. Much of that work used the embryonic chick corneal epithelial model. This review highlights many of the discoveries that she made using this model. Hay was the first to show that embryonic corneal epithelial cells produce fibrillar collagen. Her lab was among the first to demonstrate that corneal epithelial cells respond to a collagenous substrate by increasing ECM production, and that purified ECM molecules, added to cultures of epithelial sheets, induce a reorganization of the actin cytoskeleton. These data led to the first theories of cell-matrix interactions, illustrated in a 'hands across the membrane' sketch drawn by Hay. Recent work with the epithelial sheet model system has elucidated many of the signal transduction pathways required for actin reorganization in response to the ECM. In all, this body of work has amply supported Hay's belief that the embryonic corneal epithelium is a powerful model system for exploring the role of the ECM in regulating the cytoskeleton, in directing cell migration, and in profoundly influencing cell growth and differentiation during development.

Vitamin A depletion causes oxidative stress, mitochondrial dysfunction, and PARP-1-dependent energy deprivation.

A significant unresolved question is how vitamin A deprivation causes, and why retinoic acid fails to reverse, immunodeficiency. When depleted of vitamin A, T cells undergo programmed cell death (PCD), which is enhanced by the natural competitor of retinol, anhydroretinol. PCD does not happen by apoptosis, despite the occurrence of shared early events, including mitochondrial membrane depolarization, permeability transition pore opening, and cytochrome c release. It also lacks caspase-3 activation, chromatin condensation, and endonuclease-mediated DNA degradation, hallmarks of apoptosis. PCD following vitamin A deprivation exhibits increased production of reactive oxygen species (ROS), drastic reductions in ATP and NAD(+) levels, and activation of poly-(ADP-ribose) polymerase (PARP) -1. These latter steps are causative because neutralizing ROS, imposing hypoxic conditions, or inhibiting PARP-1 by genetic or pharmacologic approaches prevents energy depletion and PCD. The data highlight a novel regulatory role of vitamin A in mitochondrial energy homeostasis.

Myosin flares and actin leptomeres as myofibril assembly/disassembly intermediates in sonic muscle fibers.

The sonic muscle of type 1 male midshipman fish produces loud and enduring mating calls. Each sonic muscle fiber contains a tubular contractile apparatus with radially arranged myofibrillar plates encased in a desmin-rich cytoskeleton that is anchored to broad Z bands (approximately 1.2 micro m wide). Immunomicroscopy has revealed patches of myosin-rich "flares" emanating from the contractile tubes into the peripheral sarcoplasm along the length of the fibers. These flares contain swirls of thick filaments devoid of associated thin filaments. In other regions of the sarcoplasm at the inner surface of the sarcolemma and near Z bands, abundant ladder-like leptomeres occur with rungs every 160 nm. Leptomeres consist of dense arrays of filaments (approximately 4 nm) with a structure that resembles myofibrillar Z band structure. We propose that flares and leptomeres are distinct filamentous arrays representing site-specific processing of myofibrillar components during the assembly and disassembly of the sarcomere. Recent reports that myosin assembles into filamentous aggregates before incorporating into the A band in the skeletal muscles of vertebrates and Caenorhabditis elegans suggest that sonic fibers utilize a similar pathway. Thus, sonic muscle fibers, with their tubular design and abundant sarcoplasmic space, may provide an attractive muscle model to identify myofibrillar intermediates by structural and molecular techniques.

Bicarbonate-responsive "soluble" adenylyl cyclase defines a nuclear cAMP microdomain.

Bicarbonate-responsive "soluble" adenylyl cyclase resides, in part, inside the mammalian cell nucleus where it stimulates the activity of nuclear protein kinase A to phosphorylate the cAMP response element binding protein (CREB). The existence of this complete and functional, nuclear-localized cAMP pathway establishes that cAMP signals in intracellular microdomains and identifies an alternate pathway leading to CREB activation.

Evidence for an extracellular matrix bridge guiding proepicardial cell migration to the myocardium of chick embryos.

During heart development, the proepicardium (PE) gives rise to cells of the epicardial epithelium, connective tissue of the subepicardium and the myocardium, and smooth muscle, endothelium, and connective tissue of the coronary arteries. The PE arises as an outgrowth of the pericardial serosa at embryonic day 2 (Hamburger and Hamilton stage [HH] 14) of chick development. Between stages HH14 and HH17, multicellular villous projections extend from the PE toward the dorsal aspect of the lesser curvature of the myocardium. On reaching the atrioventricular (AV) junction, the cells spread over the myocardium, eventually enveloping the complete heart surface as a simple squamous epithelium. Although the lineage of the PE cells is well established, it remains uncertain how cells of the PE reach the myocardial surface and specifically target the AV junction. By using a combination of serial section reconstructions, immunofluorescence, and electron microscopy, we have identified an extracellular matrix bridge (ECMB) spanning the coelomic cavity between the PE and the myocardium. The ECMB is first detectable at HH14 and persists until the PE contacts the bare myocardial surface. This ECMB stains intensely with ruthenium red and Alcian blue, contains heparan sulfate and fibronectin, and exhibits both fibrillar and globular ultrastructure, reminiscent of proteoglycans. After PE attachment to the myocardium (HH16-HH17), the subepicardium exhibited strong staining for heparan sulfate. Heparinase injection into the pericardial coelom at HH15 resulted in aberrant development of the primordial epicardium. On the basis of these studies, we suggest that the ECMB may participate in migration and targeting of the PE to the myocardium.

Compartmentalization of bicarbonate-sensitive adenylyl cyclase in distinct signaling microdomains.

Intracellular targets of the ubiquitous second messenger cAMP are located at great distances from the most widely studied source of cAMP, the G protein responsive transmembrane adenylyl cyclases. We previously identified an alternative source of cAMP in mammalian cells lacking transmembrane spanning domains, the "soluble" adenylyl cyclase (sAC). We now demonstrate that sAC is distributed in specific subcellular compartments: mitochondria, centrioles, mitotic spindles, mid-bodies, and nuclei, all of which contain cAMP targets. Distribution at these intracellular sites proves that adenylyl cyclases are in close proximity to all cAMP effectors, suggesting a model in which local concentrations of cAMP are regulated by individual adenylyl cyclases targeted to specific microdomains throughout the cell.

The C-terminal IgI domains of myosin-binding proteins C and H (MyBP-C and MyBP-H) are both necessary and sufficient for the intracellular crosslinking of sarcomeric myosin in transfected non-muscle cells.

Using the COS cell transfection assay developed previously, we examined which domains of myosin-binding proteins C and H (MyBP-C and MyBP-H) are involved in intracellular interactions with sarcomeric myosin heavy chain (MyHC). Earlier studies demonstrated that overexpression of sarcomeric MyHC in COS cells results in the cytoplasmic assembly of anisotropic, spindle-like aggregates of myosin-containing filaments in the absence of other myofibrillar proteins. When the same sarcomeric MyHC was co-expressed with either MyBP-C or MyBP-H, prominent cable-like co-polymers of MyHC and the MyBPs formed in the cytoplasm instead of the spindle-like aggregates formed by MyHC alone. In vitro binding assays have shown that the C-terminal IgI domain of both MyBP-C (domain C10) and MyBP-H (domain H4) contains the light meromyosin (LMM)-binding sites of each molecule, but this domain cannot explain all of the intracellular properties of the molecules. For example, domains C7-C10 of MyBP-C and domains H1-H4 of MyBP-H are required for the faithful targeting of these proteins to the A-bands of myofibrils in skeletal muscle. Using truncation mutants of both MyBPs tagged with either green fluorescent protein (GFP) or c-myc, we now demonstrate that the last four domains of both MyBP-C and MyBP-H colocalize with the full-length proteins in the MyHC/MyBP cable polymers when co-transfected with MyHC in COS cells. Deletion of the C-terminal IgI domain in either MyBP-C or MyBP-H abrogated cable formation, but the expressed proteins could still colocalize with MyHC-containing filament aggregates. Co-expression of only the C-terminal IgI domain of MyBP-C with sarcomeric MyHC was sufficient for cable formation and colocalization with myosin. We conclude that the C-terminal IgI domains of both MyBP-H and MyBP-C are both necessary and sufficient for inducing MyHC/MyBP cable formation in this COS cell system. However, there must be other myosin-binding sites in MyBP-C and MyBP-H that explain the co-distribution of these proteins with myosin filaments in the absence of cable formation. These latter sites are neither sufficient nor required for cable formation.

DIRECT ISOLATION OF NATIVE THIN FILAMENTS FROM EMBRYONIC MUSCLE CELLS.

A method is presented for the release of "native" thin filaments from 13-day old embryonic chick muscle without tryptic digestion or desoxycholate (DOC) solubilization of Z bands. The isolated filaments were 50-60 Å in diameter, of variable length, and formed "arrowhead-like" complexes with heavy meromyosin (HMM). In addition, the filaments interacted with purified myosin to form actomyosin as effectively as action extracted from an acetone powder of muscle. The Mg++ -dependent ATPase activity and extent of superprecipitation of the synthetic actomyosin required a low concentration of Ca++ , strongly suggesting the presence of troponin and tropomyosin on the thin filaments isolated from muscle at this stage of embryogenesis. The native thin filaments were more sensitive to trypsin than synthetic F-actin prepared from an acetone powder based on measurements of flow birefrengence, viscosity and the ability to activate myosin ATPase.