The Enigmatic Metallothioneins: A Case of Upward-Looking Research.

In the mid-1950s, Bert Lester Vallee and his colleague Marvin Margoshes discovered a molecule referred to today as metallothionein (MT). Meanwhile, MTs have been shown to be common in many biological organisms. Despite their prevalence, however, it remains unclear to date what exactly MTs do and how they contribute to the biological function of an organism or organ. We investigate why biochemical research has not yet been able to pinpoint the function(s) of MTs. We shall systematically examine both the discovery of and recent research on Dr. Vallee's beloved family of MT proteins utilizing tools from philosophy of science. Our analysis highlights that Vallee's initial work exhibited features prototypical of a developing research tradition: it was upward-looking, exploratory, and utilized mere interactions. Since the 1960s, MT research has increasingly become intervention- and hypothesis-based while it remained largely upward-looking in character. Whilst there is no reason to think that upward-looking research cannot successfully yield structure-function mappings, it has not yet been successful in the case of MTs. Thus, we suggest it might be time to change track and consider other research strategies looking into the evolution of MTs. Recent studies in mollusks render research in this direction worthy of pursuit.

Specific, sensitive, high-resolution detection of protein molecules in eukaryotic cells using metal-tagging transmission electron microscopy.

More than any other methodology, transmission electron microscopy (TEM) has contributed to our understanding of the architecture and organization of cells. With current detection limits approaching atomic resolution, it will ultimately become possible to ultrastructurally image intracellular macromolecular assemblies in situ. Presently, however, methods to unambiguously identify proteins within the crowded environment of the cell's interior are lagging behind. We describe an approach, metal-tagging TEM (METTEM), that allows detection of intracellular proteins in mammalian cells with high specificity, exceptional sensitivity, and at molecular scale resolution. In live cells treated with gold salts, proteins bearing a small metal-binding tag will form 1-nm gold nanoclusters, readily detectable in electron micrographs. The applicability and strength of METTEM is demonstrated by a study of Rubella virus replicase and capsid proteins, which revealed virus-induced cell structures not seen before.

Metallothionein as a clonable high-density marker for cryo-electron microscopy.

Cryo-electron microscopy is expanding its scope from macromolecules towards much larger and more complex cellular specimens such as organelles, cells and entire tissues. While isolated macromolecular specimens are typically composed of only very few different components that may be recognized by their shape, size or state of polymerization, cellular specimens combine large numbers of proteinaceous structures as well as nucleic acids and lipid arrays. Consequently, an unambiguous identification of these structures within the context of a whole cell may create a very difficult challenge. On plastic-embedded specimens, or Tokuyasu sections (Tokuyasu, 1980), epitopes that are exposed at the surface can be tagged by antibodies. However, vitrified sections have to be kept at strict cryo-conditions (below -140 °C) and therefore do not allow any post-sectioning treatment of the specimens other than data acquisition in the microscope. Hence, the labels have to be placed into the specimen before freezing. Here we report on the application of a small metal-clustering protein, metallothionein (MTH), as a clonable label capable of clustering metal atoms into a high-density particle with high spatial resolution. We tested MTH as a label for kinesin-decorated microtubules (MTs) as well as the building blocks of desmin intermediate filaments (IFs).

Cellular electron microscopy imaging reveals the localization of the Hfq protein close to the bacterial membrane.

BACKGROUND: Hfq is a bacterial protein involved in several aspects of nucleic acid transactions, but one of its best-characterized functions is to affect the post-transcriptional regulation of mRNA by virtue of its interactions with stress-related small regulatory (sRNA). METHODOLOGY AND PRINCIPAL FINDING: By using cellular imaging based on the metallothionein clonable tag for electron microscopy, we demonstrate here that in addition to its localization in the cytoplasm and in the nucleoid, a significant amount of Hfq protein is located at the cell periphery. Simultaneous immunogold detection of specific markers strongly suggests that peripheral Hfq is close to the bacterial membrane. Because sRNAs regulate the synthesis of several membrane proteins, our result implies that the sRNA- and Hfq-dependent translational regulation of these proteins takes place in the cytoplasmic region underlying the membrane. CONCLUSIONS: This finding supports the proposal that RNA processing and translational machineries dedicated to membrane protein translation may often be located in close proximity to the membrane of the bacterial cell.

Electron microscopic analysis of a fusion protein of postsynaptic density-95 and metallothionein in cultured hippocampal neurons.

The subcellular localization of biomolecules at high resolution has traditionally been investigated by combining transmission electron microscopy (TEM) and chemical staining with heavy metals or immuno-based labeling with gold-conjugated antibodies. Here, we employ genetically encoded tags to examine the localization of proteins in transfected cultured cells by TEM. We purified a fusion protein of postsynaptic density-95 (PSD-95) coupled to three tandem repeats of metallothionein (MT) (PDS-95-3MT) from COS7 cells grown in the presence of Cd2+. PSD-95-3MT was detected as black particles by TEM. To visualize the subcellular localization of PSD-95-3MT, expression constructs encoding this fusion protein were transfected into primary hippocampal neurons cultured in medium containing Cd2+. The subcellular accumulation of PSD-95-3MT and Cd2+ provided excellent contrast in TEM micrographs. To address if genetically encoded tags affect the function of the target proteins, we found that the conjugation of 3MT to PSD-95 did not alter its association with known binding partners. These results demonstrate that 3MT coordinating Cd2+ is a valuable genetically encoded tag to study the localization of proteins by TEM.

A genetically encoded metallothionein tag enabling efficient protein detection by electron microscopy.

The observation of biological materials by transmission electron microscopy (TEM) frequently requires the use of negative staining and/or immuno-gold labeling to visualize or identify the specimen, but these techniques are limited. In contrast, genetic labeling with green fluorescent protein (GFP) and its homologs have led to rapid advances in the observation of proteins of interest in cells by light microscopy (LM). These fluorescent tags allow for the visualization of dynamic processes in live cells without the use of secondary reagents. Here, we report the development of an artificial metalloprotein fusion protein expressed in Escherichia coli grown in Cd(2+)-containing medium that allows for efficient protein detection by TEM without additional staining steps. We linked the subunits of the bacterial 14-mer protein GroEL with three repeats of metallothionein (3MT). The 3MT-fused GroEL (GroEL-14(3MT)) was successfully expressed in E. coli, and the purified protein included 250 cadmium atoms per molecule on average. Cd(2+)-bound GroEL-14(3MT) was detected by TEM in the absence of negative staining on a carbon grid, and the particle densities of GroEL-14(3MT) were much greater than those of untagged GroEL in vitreous ice. Taken together, our data indicate that the 3MT tag provides a promising means of allowing the identification of oligomeric proteins isolated from cells in the absence of other detection techniques.

Mn,Cd-metallothionein-2: a room temperature magnetic protein.

Naturally occurring metallothionein (MT) is a metal binding protein, which binds to seven Zn2+ through 20 conserved cysteines and forms two metal binding clusters with a Zinc-Blende structure. We demonstrate that the MT, when substituting the Zn2+ ions by Mn2+ and Cd2+, exhibits magnetic hysteresis loop observable by SQUID from 10 to 330 K. The magnetic moment may have originated from the bridging effect of the sulfur atoms between the metal ions that leads to the alignment of the electron spins of the Mn2+ ions inside the clusters. The protein backbone may restrain the net spin moment of Mn2+ ions from thermal fluctuation. The modified magnetic-metallothionein is a novel approach to creating molecular magnets with operating temperatures up to 330 K.

The ATP/metallothionein interaction: NMR and STM.

We have previously established that ATP binds to mammalian metallothionein-2 (MT). The interaction between ATP and MT and the associated conformational change of the protein affect the sulfhydryl reactivity and zinc transfer potential of MT [Jiang, L.-J., Maret, W., and Vallee, B. L. (1998) The ATP-metallothionein complex. Proc. Natl. Acad. Sci. U.S.A. 95, 9146-9149]. NMR spectroscopic investigations have now provided further evidence for the interaction. (35)Cl NMR spectroscopy has further identified chloride as an additional biological MT ligand, which can interfere with the interaction of ATP with MT. (1)H NMR/TOCSY spectra demonstrate that ATP binding affects the N- and C-terminal amino acids of the MT molecule. Scanning tunneling microscopy recorded images of single MT molecules in buffered solutions. Moreover, this technique demonstrates that the otherwise nearly linear MT molecule bends by about 20 degrees at its central hinge region between the domains in the presence of ATP. These results may bear on the development of mild obesity in MT null mice and the role of MT in the regulation of energy balance. The interaction suggests a mechanism for the cellular translocation, retention, and reactivity of the ATP*MT complex in the mitochondrial intermembrane space. Both MT and ATP are localized there, and MT and thionein alternately bind and release zinc, thereby affecting mitochondrial respiration.

New methods for depositing and imaging molecules in scanning tunneling microscopy.

Methods and apparatus are described to deposit and image molecules by scanning tunneling microscopy (STM) under an inert atmosphere. Three methods of applying molecules have been evaluated: equilibrium adsorption from the vapor phase, sublimation, and electrospraying. Using these methods, a variety of organic and biopolymer molecules have been deposited and imaged on graphite and on gold (111), grown epitaxially on mica. Compared with alternatives, such as the use of high vacuum apparatus or glove boxes, these procedures offer some important advantages: they are inexpensive, convenient, and more rapid. Mercaptoethanol, ethanolamine, ethanol, acetic acid, and water produce two-dimensional crystalline adlayers on gold substrates, when they are introduced into the scanning cell as vapors. These adlayers are assumed to involve hydrogen bonding of the molecules to an oxide of gold formed on the surface. Electrospraying protein solutions on gold surfaces yielded images of individual protein molecules with lateral dimensions close to those measured by X-ray analysis, and thicknesses of 0.6-1.3 nm. In the case of metallothionein, the known internal domain structure of the molecule was reproducibly observed. No detailed internal structure could be resolved in the other examples examined.

A two-dimensional NMR study of Co(II)7 rabbit liver metallothionein.

The 600-MHz 1H-NMR NOESY spectra on Co(II)7-reconstituted metallothionein (Co7MT), exhibiting hyperfine signals in the range 350 ppm to -50 ppm, with nuclear relaxation times of the order of a few milliseconds, have been measured and several interproton connectivities have been detected. To our knowledge, this is the largest spectral window ever reported for a two-dimensional 1H-NMR spectrum in the case of a paramagnetic metalloprotein. No scalar connectivities could be detected. The hyperfine-shifted signals belong to the cysteine-ligand protons of the Co4S11 cluster of Co7MT. Together with results from one-dimensional NOE experiments, the two-dimensional experiments allowed us to proceed with the pairwise assignment of the isotropically shifted signals of the C beta H2 groups of the metal-coordinated cysteines. With the aid of computer-graphics inspection of the four-metal-cluster domain, based on the NMR solution structure of Cd7MT, it is possible to purpose sequence-specific assignments of a few hyperfine-shifted 1H-NMR signals. In particular, a tentative assignment is given for the six signals whose shifts exhibit an antiCurie temperature dependence. The assignment relies on the theoretical model that qualitatively rationalizes the isotropic-shift pattern and its temperature dependence. Inferences on the solution structure of the Co4S11 cluster are drawn.