Lawrence E. Hightower

Guidelines for the nomenclature of the human heat shock proteins

The expanding number of members in the various human heat shock protein (HSP) families and the inconsistencies in their nomenclature have often led to confusion. Here, we propose new guidelines for the nomenclature of the human HSP families, HSPH (HSP110), HSPC (HSP90), HSPA (HSP70), DNAJ (HSP40), and HSPB (small HSP) as well as for the human chaperonin families HSPD/E (HSP60/HSP10) and CCT (TRiC). The nomenclature is based largely on the more consistent nomenclature assigned by the HUGO Gene Nomenclature Committee and used in the National Center of Biotechnology Information Entrez Gene database for the heat shock genes. In addition to this nomenclature, we provide a list of the human Entrez Gene IDs and the corresponding Entrez Gene IDs for the mouse orthologs.

Cell surface expression of heat shock proteins and the immune response.

Heat shock proteins (Hsp) inhabit intracellular locales where at least one of their functions, molecular chaperoning of other proteins, has been firmly established. However, there are also scattered reports that nucleocytoplasmic Hsp, which contain no obvious ER-Golgi targeting signal sequences, are sometimes found outside of the procaryotic and eucaryotic cells that produced them. These observations can be divided into those involving the release of intact Hsp from cells or their transfer from producer to recipient cells and those involving the display of intact Hsp, fragments derived from them and proteins with domains related to Hsp on cell surfaces. Cell biologists are primarily interested in the mechanisms by which such Hsp are released from cells. However, little is known about the cellular pathways used by these Hsp to escape from the nucleocytoplasmic compartment. Experiments indicating that inhibitors of the ER-Golgi secretory pathway do not block their release have been interpreted by some workers as evidence of a non-ERGolgi secretory pathway for nucleocytoplasmic Hsp; however, purists are awaiting a molecular mechanism before giving up the alternative interpretation that Hsp are only released by lysis of dying cells. For immunologists as well as tumor and transplantation biologists, the more interesting aspects of the externalization of Hsp are the consequences for immune responses of the various forms of Hsp which by whatever mechanism end up bound to or displayed on the surfaces of certain cell

A 16-kDa Protein Functions as a New Regulatory Protein for Hsc70 Molecular Chaperone and Is Identified as a Member of the Nm23/Nucleoside Diphosphate Kinase Family

Cytoplasmic Hsc70 is a multifunctional molecular chaperone. It is hypothesized that accessory proteins are used to specify the diverse chaperone activities of Hsc70. A 16-kDa cytosolic protein (p16) co-purified with Hsc70 obtained from a fish hepatocyte cell line, PLHC-1. Hsc70 also co-immunoprecipitated with p16 from PLHC-1 cells and fish liver. p16 was identified as a member of the Nm23/nucleoside diphosphate (NDP) kinase family based on its amino acid sequence similarity, NDP kinase activity, and recognition by anti-human NDP kinase-A antibody. This antibody also co-immunoprecipitated Hsc70 and NDP kinase from human HepG2 cells. p16 monomerized Hsc70 and released Hsc70 from pigeon cytochrome c peptide (Pc) but not from FYQLALT, a peptide specifically designed for high affinity binding. Therefore, p16 may modulate Hsc70 function by maintaining Hsc70 in a monomeric state and by dissociating unfolded proteins from Hsc70 either through protein-protein interactions or by supplying ATP indirectly through phosphate transfer. p16 did not affect basal or unfolded protein-stimulated ATPase activity of bovine brain Hsc70 using in vitro assays. Interestingly, bovine liver NDP kinase did not dissociate the Hsc70·;Pc complex. In addition, two nonconservative amino acid subsitutions were found near the amino terminus of p16. Therefore, p16 may be a unique Nm23/NDP kinase that functions as an accessory protein for cytosolic Hsc70 in eukaryotes.

Hsp70B′ regulation and function

Abstract Heat shock protein (Hsp) 70B′ is a human Hsp70 chaperone that is strictly inducible, having little or no basal expression levels in most cells. Using siRNAs to knockdown Hsp70B′ and Hsp72 in HT-29, SW-480, and CRL-1807 human colon cell lines, we have found that the two are regulated coordinately in response to stress. We also have found that proteasome inhibition is a potent activator of hsp70B′. Flow cytometry was used to assay hsp70B′ promoter activity in HT-29eGFP cells in this study. Knockdown of both Hsp70B′ and Hsp72 sensitized cells to heat stress and increasing concentrations of proteasome inhibitor. These data support the conclusion that Hsp72 is the primary Hsp70 family responder to increasing levels of proteotoxic stress, and Hsp70B′ is a secondary responder. Interestingly ZnSO4 induces Hsp70B′ and not Hsp72 in CRL-1807 cells, suggesting a stressor-specific primary role for Hsp70B′. Both Hsp70B′ and Hsp72 are important for maintaining viability under conditions that increase the accumulation of damaged proteins in HT-29 cells. These findings are likely to be important in pathological conditions in which Hsp70B′ contributes to cell survival.

Hyperbaric oxygen induces a cytoprotective and angiogenic response in human microvascular endothelial cells

A genome-wide microarray analysis of gene expression was carried out on human microvascular endothelial cells (HMEC-1) exposed to hyperbaric oxygen treatment (HBOT) under conditions that approximated clinical settings. Highly up-regulated genes included immediate early transcription factors (FOS, FOSB, and JUNB) and metallothioneins. Six molecular chaperones were also up-regulated immediately following HBOT, and all of these have been implicated in protein damage control. Pathway analysis programs identified the Nrf-2-mediated oxidative stress response as one of the primary responders to HBOT. Several of the microarray changes in the Nrf2 pathway and a molecular chaperone were validated using quantitative PCR. For all of the genes tested (Nrf2, HMOX1, HSPA1A, M1A, ACTC1, and FOS), HBOT elicited large responses, whereas changes were minimal following treatment with 100% O2 in the absence of elevated pressure. The increased expression of immediate early and cytoprotective genes corresponded with an HBOT-induced increase in cell proliferation and oxidative stress resistance. In addition, HBOT treatment enhanced endothelial tube formation on Matrigel plates, with particularly dramatic effects observed following two daily HBO treatments. Understanding how HBOT influences gene expression changes in endothelial cells may be beneficial for improving current HBOT-based wound-healing protocols. These data also point to other potential HBOT applications where stimulating protection and repair of the endothelium would be beneficial, such as patient preconditioning prior to major surgery.

8 Interactions of Vertebrate hsc70 and hsp70 with Unfolded Proteins and Peptides

I. INTRODUCTION This chapter is the companion to McKay’s chapter in this volume on the ATP-binding domain of the vertebrate hsp70 protein family. We have attempted to pull together what is known about the interactions of the carboxy-terminal domains of vertebrate hsc70 and hsp70 with unfolded proteins and peptides and about the interactions between the peptide-binding and ATPase domains. The molecular structure of the crystallized ATP-binding domain has been determined by X-ray diffraction (Flaherty et al. 1990); however, the three-dimensional structure of the peptide-binding domain is not known. Therefore, computerized structural predictions have been used to model the carboxy-terminal domain. Because of the manner in which information on the functions of this protein family was initially developed, primarily through serendipitous discoveries of roles in normal cellular processes, much more is known about the constitutive or cognate members such as hsc70 than the stress-inducible members (hsp70). Thus, evidence of “molecular chaperone” functions comes primarily from studies of the cognates. Molecular chaperones are proteins that facilitate the folding or assembly and disassembly of other proteins but are not part of the finished structure (for recent reviews, see Ang et al. 1991; Craig et al. 1993; Georgopoulos and Welch 1993; Hendrick and Hartl 1993). The current hypotheses regarding chaperoning mechanisms for the hsp70 family include (1) binding to nascent polypeptides to delay folding until synthesis of the polypeptide chain is completed and all of the information needed for folding is present, (2) delaying folding until the polypeptide reaches the appropriate cellular compartment, (3)...

Quantitative evidence that both Hsc70 and Hsp70 contribute to thermal adaptation in hybrids of the livebearing fishes Poeciliopsis

The 70-kilodalton heat shock protein family is composed of both environmentally inducible (Hsp) and constitutively expressed (Hsc) family members. While the role of the constitutively expressed stress proteins in thermotolerance is largely unknown, de novo expression of stress proteins in response to elevated temperatures has been associated with increased thermotolerance in many cell lines, developing embryos and adult organisms. Distinct, hemiclonal hybrids between the livebearing fish species Poeciliopsis monacha and P. lucida varied in their abilities to survive temperature stress, with survival being greatest when rates of temperature increase to 40 degrees C were slowest and when P. monacha genomes were combined with a sympatric P. lucida genome. Quantification of Hsp70 under heat shock conditions and Hsc70 under normal physiological conditions indicated that variation in survival among hemiclones was best explained by the combined effects of these two proteins. Similar complex interactions between maternal and paternal genomes and rate of temperature increase were found to underlie patterns of survival, Hsp70 accumulation and Hsc70 abundance. These data suggest that the relationship between Hsps and thermotolerance is more intricate than previously thought and that Hsps contribute to thermal adaptation in these fishes through genetic interactions specific to particular environments.

Distinguishing integral and receptor-bound heat shock protein 70 (Hsp70) on the cell surface by Hsp70-specific antibodies.

Cell Stress & Chaperones journal has become a major outlet for papers and review articles about anti-heat shock protein (HSP) antibodies. In the last decade, it became evident that apart from their intracellular localization, members of the heat shock protein 90 (Hsp90; HSPC) and Hsp70 (HSPA) family are also found on the cell surface. In this review, we will focus on Hsp70 (HSPA1A), the major stress-inducible member of the human Hsp70 family. Depending on the cell type, the membrane association of Hsp70 comes in two forms. In tumor cells, Hsp70 appears to be integrated within the plasma membrane, whereas in non-malignantly transformed (herein termed normal) cells, Hsp70 is associated with cell surface receptors. This observation raises the question whether or not these two surface forms of Hsp70 in tumor and normal cells can be distinguished using Hsp70 specific antibodies. Presently a number of Hsp70 specific antibodies are commercially available. These antibodies were generated by immunizing mice either with recombinant or HeLa-derived human Hsp70 protein, parts of the Hsp70 protein, or with synthetic peptides. This review aims to characterize the binding of different anti-human Hsp70 antibodies and their capacity to distinguish between integrated and receptor-bound Hsp70 in tumor and normal cells.

Effects of heat shock, stannous chloride, and gallium nitrate on the rat inflammatory response

Abstract Heat and a variety of other stressors cause mammalian cells and tissues to acquire cytoprotection. This transient state of altered cellular physiology is nonproliferative and antiapoptotic. In this study, male Wistar rats were stress conditioned with either stannous chloride or gallium nitrate, which have immunosuppressive effects in vivo and in vitro, or heat shock, the most intensively studied inducer of cytoprotection. The early stages of inflammation in response to topical suffusion of mesentery tissue with formyl-methionyl-leucyl-phenylalanine (FMLP) were monitored using intravital microscopy. Microvascular hemodynamics (venular diameter, red blood cell velocity [Vrbc], white blood cell [WBC] flux, and leukocyte-endothelial adhesion [LEA]) were used as indicators of inflammation, and tissue levels of inducible Hsp70, determined using immunoblot assays, provided a marker of cytoprotection. None of the experimental treatments blocked decreases in WBC flux during FMLP suffusion, an indicator of increased low-affinity interactions between leukocytes and vascular endothelium known as rolling adhesion. During FMLP suffusion LEA, an indicator of firm attachment between leukocytes and vascular endothelial cells increased in placebo and gallium nitrate-treated animals but not in heat- and stannous chloride–treated animals, an anti-inflammatory effect. Hsp70 was not detected in aortic tissue from placebo and gallium nitrate–treated animals, indicating that Hsp70-dependent cytoprotection was not present. In contrast, Hsp70 was detected in aortic tissues from heat- and stannous chloride–treated animals, indicating that these tissues were in a cytoprotected state that was also an anti-inflammatory state.

Hyperbaric oxygen treatment induces antioxidant gene expression

Although the underlying molecular causes of aging are not entirely clear, hormetic agents like exercise, heat, and calorie restriction may generate a mild pro‐oxidant stress that induces cell protective responses to promote healthy aging. As an individual ages, many cellular and physiological processes decline, including wound healing and reparative angiogenesis. This is particularly critical in patients with chronic non‐healing wounds who tend to be older. We are interested in the potential beneficial effects of hyperbaric oxygen as a mild hormetic stress on human microvascular endothelial cells. We analyzed global gene expression changes in human endothelial cells following a hyperbaric exposure comparable to a clinical treatment. Our analysis revealed an upregulation of antioxidant, cytoprotective, and immediate early genes. This increase coincided with an increased resistance to a lethal oxidative stress. Our data indicate that hyperbaric oxygen can induce protection against oxidative insults in endothelial cells and may provide an easily administered hormetic treatment to help promote healthy aging.