Growth Curves of Subependymal Giant Cell Tumors in Tuberous Sclerosis Complex.

BACKGROUND AND PURPOSE: Growth of subependymal giant cell tumor and subependymal nodules has not been well-characterized. The purpose of this study was to determine whether growth curves can differentiate subependymal giant cell tumors from subependymal nodules. MATERIALS AND METHODS: Brain MR imaging of patients with tuberous sclerosis complex were retrospectively reviewed from 2002 to 2018. All lesions in the region of the foramen of Monro were measured. Lesions were categorized on the basis of maximal diameter at the most recent scan: small lesions (<1 cm), indeterminate lesions (>1 cm), and resected lesions (>1 cm and surgically resected). Growth velocity and acceleration on serial imaging were analyzed, and growth rates were calculated between 0 and 20 years of age and compared among the 3 categories. RESULTS: Forty-one patients were analyzed. The average age at the earliest scan was 5.9 (SD = 5.7) years. One hundred twenty-six small, 27 indeterminate, and 10 resected lesions were measured. Subependymal giant cell tumors grew faster than indeterminate lesions between 6 and 15 years of age. Indeterminate lesions grew faster than small lesions at 0-10 years of age. Resected lesions showed increased velocity and acceleration of growth compared with indeterminate lesions and small lesions on serial imaging. CONCLUSIONS: Growth differentiates subependymal nodules and subependymal giant cell tumors within the first 20 years of life, and the use of velocity and acceleration of growth may refine the diagnostic criteria of subependymal giant cell tumors. Additionally, 6-15 years of age may be an important period to monitor subependymal giant cell tumors at the foramen of Monro because increased growth may help to identify subependymal giant cell tumors that will continue to grow and result in obstructive hydrocephalus.

Differential display analysis of gene expression in invertebrates.

Screening for differentially expressed genes is a straightforward approach to study the molecular basis for changes in gene expression. Differential display analysis has been used by investigators in diverse fields of research since it was developed. Differential display has also been the approach of choice to investigate changes in gene expression in response to various biological challenges in invertebrates. We review the application of differential display analysis of gene expression in invertebrates, and provide a specific example using this technique for novel gene discovery in the nematode Caenorhabditis elegans.

Protective effects of aspirin and vitamin E (alpha-tocopherol) against copper- and cadmium-induced toxicity.

A 24-h exposure to copper (400 microM, 600 microM) or cadmium (5 microM, 10 microM) significantly reduces the viability of COS-7 cells. A 2-h preincubation with vitamin E does not protect COS-7 cells from copper-induced toxicity, but does protect against cadmium-induced toxicity. Preincubation with aspirin protects cells from both copper- and cadmium-induced toxicity. A combination of aspirin and vitamin E (10 microM and 25 microM, respectively) increases cell viability in copper-exposed cells in a clearly additive manner, while in cadmium-exposed cells the effects are slightly additive. These results indicate that aspirin and vitamin E can protect cells from metal-induced toxicity. Differences in the protective effects of aspirin and vitamin E on copper versus cadmium-induced toxicity may be due to alternative mechanisms of metal toxicity or antioxidant activity.

Characterization of a cadmium-inducible isoform of pyruvate carboxylase from Caenorhabditis elegans.

A homologue of pyruvate carboxylase was isolated as an expressed sequence tag during the identification of cadmium-responsive genes in Caenorhabditis elegans. The C. elegans protein, designated PYC-1, is predicted to contain 1,175 amino acids with a molecular mass of 129,284. Amino acid sequence analysis indicates that PYC-1 will be translocated into mitochondria. PYC-1 has high levels of amino acid sequence identity with other pyruvate carboxylases. The highest levels of identity are in the putative transcarboxylation, biotin carboxylation and biotin carboxyl carrier domains.

Aspartic proteases from the nematode Caenorhabditis elegans. Structural organization and developmental and cell-specific expression of asp-1.

A Caenorhabditis elegans gene (asp-1) and cDNA that encode a homologue of cathepsin D aspartic protease were cloned and characterized. The asp-1 mRNA is transcribed from a single exon, and it begins with the SL1 trans-splice leader sequence. The protein (ASP-1) is expressed as a 396-amino acid, 42.7-kDa pre-pro-peptide that is post-translationally processed into a approximately 40-kDa lysosomal protein. ASP-1 shares approximately 60% sequence identity with the aspartic protease precursor from the nematode Strongyloides stercoralis. The amino acid sequences adjacent to the two active site aspartic acid residues in ASP-1 are 100% identical to those in other eukaryotic aspartic proteases. In addition, ASP-1 contains conserved, potential disulfide bond-forming cysteine residues and N-glycosylation sites. The asp-1 gene is exclusively transcribed in the intestinal cells, with the highest levels of expression observed at late embryonic and early larval stages of development. asp-1 transcription is not observed in adult nematodes or mature larvae. Furthermore, transcription predominantly occurs in eight anterior cells of the intestine (int6-int8). Analyses of ASP-1 nucleotide and amino acid sequences revealed the presence of five additional C. elegans aspartic proteases.

Regulation of metallothionein gene transcription. Identification of upstream regulatory elements and transcription factors responsible for cell-specific expression of the metallothionein genes from Caenorhabditis elegans.

Metallothioneins are small, cysteine-rich proteins that function in metal detoxification and homeostasis. Metallothionein transcription is controlled by cell-specific factors, as well as developmentally modulated and metal-responsive pathways. By using the nematode Caenorhabditis elegans as a model system, the mechanism that controls cell-specific metallothionein transcription in vivo was investigated. The inducible expression of the C. elegans metallothionein genes, mtl-1 and mtl-2, occurs exclusively in intestinal cells. Sequence comparisons of these genes with other C. elegans intestinal cell-specific genes identified multiple repeats of GATA transcription factor-binding sites (i.e. GATA elements). In vivo deletion and site-directed mutation analyses confirm that one GATA element in mtl-1 and two in mtl-2 are required for transcription. Electrophoretic mobility shift assays show that the C. elegans GATA transcription factor ELT-2 specifically binds to these elements. Ectopic expression of ELT-2 in non-intestinal cells of C. elegans activates mtl-2 transcription in these cells. Likewise, mtl-2 is not expressed in nematodes in which elt-2 has been disrupted. These results indicate that cell-specific transcription of the C. elegans metallothionein genes is regulated by the binding of ELT-2 to GATA elements in these promoters. Furthermore, a model is proposed where ELT-2 constitutively activates metallothionein expression; however, a second metal-responsive factor prevents transcription in the absence of metals.

Cadmium-regulated genes from the nematode Caenorhabditis elegans. Identification and cloning of new cadmium-responsive genes by differential display.

The transition metal cadmium is a pervasive and persistent environmental contaminant that has been shown to be both a human toxicant and carcinogen. To inhibit cadmium-induced damage, cells respond by increasing the expression of genes encoding stress-response proteins. In most cases, the mechanism by which cadmium affects the expression of these genes remains unknown. It has been demonstrated in several instances that cadmium activates gene transcription through signal transduction pathways, mediated by protein kinase C, cAMP-dependent protein kinase, or calmodulin. A codicil is that cadmium should influence the expression of numerous genes. To investigate the ability of cadmium to affect gene transcription, the differential display technique was used to analyze gene expression in the nematode Caenorhabditis elegans. Forty-nine cDNAs whose steady-state levels of expression change 2-6-fold in response to cadmium exposure were identified. The nucleotide sequences of the majority of the differentially expressed cDNAs are identical to those of C. elegans cosmids, yeast artificial chromosomes, expressed sequence tags, or predicted genes. The translated amino acid sequences of several clones are identical to C. elegans metallothionein-1, HSP70, collagens, and rRNAs. In addition, C. elegans homologues of pyruvate carboxylase, DNA gyrase, beta-adrenergic receptor kinase, and human hypothetical protein KIAA0174 were identified. The translated amino acid sequences of the remaining differentially expressed cDNAs encode novel proteins.

Structure and expression of the Caenorhabditis elegans protein kinase C2 gene. Origins and regulated expression of a family of Ca2+-activated protein kinase C isoforms.

The molecular and cellular basis for concerted Ca2+/lipid signaling in Caenorhabditis elegans was investigated. A unique gene (pkc-2) and cognate cDNAs that encode six Ca2+/diacylglycerol-stimulated PKC2 isoenzymes were characterized. PKC2 polypeptides (680-717 amino acid residues) share identical catalytic, Ca2+-binding, diacylglycerol-activation and pseudosubstrate domains. However, sequences of the N- and C-terminal regions of the kinases diverge. PKC2 diversity is partly due to differential activation of transcription by distinct promoters. Each promoter precedes an adjacent exon that encodes 5'-untranslated RNA, an initiator AUG codon and a unique open reading frame. PKC2 mRNAs also incorporate one of two 3'-terminal exons via alternative splicing. Cells that are capable of receiving and propagating signals carried by Ca2+/diacylglycerol were identified by assessing activities of pkc-2 gene promoters in transgenic C. elegans and visualizing the distribution of PKC2 polypeptides via immunofluorescence. Highly-selective expression of certain PKC2 isoforms was observed in distinct subsets of neurons, intestinal and muscle cells. A low level of PKC2 isoforms is observed in embryos. When L1 larvae hatch and interact with the external environment PKC2 content increases 10-fold. Although 77- and 78-kDa PKC2 isoforms are evident throughout post-embryonic development, an 81-kDa isoform appears to be adapted for function in L1 and L2 larvae.

Molecular characterization of a novel, developmentally regulated small embryonic chaperone from Caenorhabditis elegans.

Low molecular weight chaperones inhibit protein aggregation and facilitate refolding of partially denatured polypeptides in cells subjected to physical and chemical stresses. The nematode Caenorhabditis elegans provides a system amenable for investigations on roles for chaperone proteins in normal homeostasis and development. We characterized a C. elegans gene and cDNAs that encode a novel, small embryonic chaperone-like protein (SEC-1) that is composed of 159 amino acids. The central core of SEC-1 (residues 45-126) is approximately 40% identical with a corresponding segment of mammalian Hsp27 and alphaB crystallin. Expression of SEC-1 in Escherichia coli confers thermotolerance on the bacterium. SEC-1 mRNA is evident only in C. elegans oocytes and developing embryos. Translation and accumulation of SEC-1 protein is temporally coupled with a prolonged burst of intense protein synthesis and rapid mitogenesis during early embryogenesis. As the rate of protein synthesis decreases during late embryogenesis, levels of SEC-1 and its cognate mRNA decline precipitously. Induction/deinduction of SEC-1 is precisely regulated by intrinsic developmental factors rather than extrinsic stresses. In vivo injection of C. elegans oocytes with antisense oligonucleotides that complement the 5'-end of SEC-1 mRNA arrests nematode development at an early stage after fertilization. Thus, SEC-1 appears to be adapted to perform essential functions in early embryogenesis.

Structure and expression of novel spliced leader RNA genes in Caenorhabditis elegans.

Approximately 25% of Caenorhabditis elegans genes are organized as operons. Polycistronic transcripts are converted to monocistronic mRNAs by 3' cleavage/polyadenylation and 5' trans-splicing with untranslated, 5' termini of mRNAs encoded by downstream genes in operons are acceptors for > or = 7 recently discovered "novel" SLs and a classical SL (SL2). Diversity in SL exons is now partly explained by the discovery and characterization of five novel genes that encode C. elegans SL RNAs. These novel SL RNAs contain a 22- or 23-nucleotide SL followed by conserved splice donor and downstream sequences that are essential for catalysis of trans-splicing reactions. The SL3 alpha, SL4, and SL5 RNA genes are tightly clustered on chromosome III; their 114-nucleotide transcripts deliver three distinct SLs to mRNAs. The SL3 beta and SL3 gamma RNA genes are on chromosome I, but are not tightly linked. SL RNAs 3 alpha, 3 beta, and 3 gamma provide identical 5' leader exons, although their 3' sequences diverge. Transcription of SL 3-5 RNA genes appears to be driven by flanking DNA elements that are homologous with segments of promoters for the C. elegans SL2 RNA and small nuclear RNA genes. RNase protection assays demonstrated that novel SL RNAs are transcribed in vivo and accumulate in the poly(A-) RNA pool. SL3 exons are transferred to mRNAs as frequently as SL2 exons. In contrast, SL4 is appended to mRNAs 10% as frequently as SL3. The abundance of SL4 RNA increased 6-fold during postembryonic development, and the SL4 RNA gene promoter is active principally in hypodermal cells.

Structure and expression of a novel, neuronal protein kinase C (PKC1B) from Caenorhabditis elegans. PKC1B is expressed selectively in neurons that receive, transmit, and process environmental signals.

The nematode Caenorhabditis elegans provides an advantageous system for investigating the regulation, expression, and functions of protein kinase C (PKC) isoforms. We cloned and characterized cDNAs encoding a novel C. elegans PKC designated PKC1B. The predicted PKC1B polypeptide contains features characteristic of the nPKC subfamily of PKC isoforms. The levels of PKC1B and its cognate mRNA vary over a 7-fold range during C. elegans postembryonic development. PKC1B protein and mRNA are abundant at the earliest larval stage, but their relative concentrations decrease coordinately in late larvae. Embryos, which are enriched in PKC1B mRNA, contain little PKC1B protein. Thus, PKC1B expression is regulated at a translational or post-translational level during early development. Cells engaged in PKC1B gene transcription were identified in transgenic C. elegans that carry the lacZ gene under the regulation of the PKC1B promoter. Staining for beta-galactosidase revealed PKC1B promoter activity exclusively in sensory neurons and interneurons. Immunofluorescence microscopy disclosed that the PKC1B polypeptide is located in the processes (axons and dendrites) and perinuclear regions of approximately 75 neurons that constitute the sensory circuitry of the nematode. The intracellular localization of PKC1B and the enzyme's differential solubility in ionic and nonionic detergents suggest that the kinase is associated with membranes and the cytoskeleton.

The novel metallothionein genes of Caenorhabditis elegans. Structural organization and inducible, cell-specific expression.

Two genes (mtl-1 and mtl-2) that encode the novel metallothioneins (MTs) of Caenorhabditis elegans (CeMTs) were cloned and characterized. Both genes contain a single intron that interrupts codon 6 and short 3'-untranslated regions. However, their promotor regions are distinctively non-homologous. The mtl-2 promoter contains a TATAA box and a single putative metal regulatory element. These elements are absent in the mtl-1 promoter. Nevertheless, both CeMT1 and CeMT2 mRNAs are induced by cadmium and contain precisely initiated, 5'-untranslated sequences. The inducibility and cell type specificity of metallothionein gene expression were investigated in transgenic C. elegans that carry the lacZ (beta-galactosidase) reporter gene under the control of an mtl-1 or mtl-2 promoter sequence. Upon treatment of transgenic C. elegans with cadmium or heat stress, the mtl-2:lacZ fusion gene is abundantly and exclusively expressed in the intestinal cells of larvae and adult animals. Expression is not detected in the absence of metal or heat shock. In contrast, an mtl-1:lacZ construct is constitutively expressed in the pharynx and induced by cadmium and heat shock in the intestinal cells of C. elegans larvae. The metal-inducible expression of the mtl-1:lacZ gene is attenuated in adult transgenic nematodes. Thus, the activity of each mtl promoter is modulated by metals as well as developmental and environmental factors.

Amplification of the metallothionein-1 and metallothionein-2 genes in copper-resistant hepatoma cells.

The molecular basis for increased metallothionein concentrations in copper-resistant hepatoma cells was examined. The copper-resistant cell line HAC600, which is maintained in 600 microns copper, had increased steady-state mRNA levels for both the metallothionein-1 (MT-1) and the metallothionein-2 (MT-2) genes. Levels of mRNA were increased 11-fold for MT-1 and 15-fold for MT-2, with no significant change in alpha-tubulin mRNA content. HAC600NM cells, which are copper-resistant cells kept in a normal copper concentration for over 1 year, also had eight- and tenfold increases in MT-1 and MT-2 mRNA levels. Nuclear run-on assays showed that MT-1 and MT-2 gene transcription was increased nine- and eightfold in HAC600 cells and seven- and tenfold in HAC600NM cells, respectively. Southern blot analysis showed amplification of both metallothionein genes in HAC600 and HAC600NM cells. Thus the molecular basis of increased metallothionein in these hepatoma cells involved a stable gene amplification of both MT genes. The greater increase in metallothionein mRNA levels in HAC600 cells relative to the changes in transcription suggests that posttranscriptional mechanisms of gene regulation may also be acting in these cells.

Inverse correlation between resistance towards copper and towards the redox-cycling compound paraquat: a study in copper-tolerant hepatocytes in tissue culture.

The essential mediatory role of copper or iron in the manifestation of paraquat toxicity has been demonstrated (Kohen and Chevion (1985) Free Rad. Res. Commun. 1, 79-88; Korbashi, P. et al. (1986) J. Biol. Chem. 261, 12472-12476). Several liver cell lines, characterized by their resistance to copper, were challenged with paraquat and their cross-resistance to paraquat and copper was studied. Cell growth and survival data showed that copper-resistant cells, containing elevated copper, are more sensitive towards paraquat than wild type cells. Copper-deprived resistant cells did not have this sensitivity. Paraquat was also shown to cause a marked degradation of cellular glutathione in all cell lines. Albeit the fact that the basal glutathione levels are higher in copper-resistant than in wild type cells, there is more paraquat-induced degradation of cellular glutathione (GSH + GSSG) in resistant cells. It is suggested that in copper-resistant cells which contain elevated levels of copper, paraquat-induced cellular injury is potentiated even where glutathione levels are elevated. Additionally, in vitro experiments are presented that support the in vivo findings demonstrating a role for copper in glutathione degradation.

Purification, characterization, and cDNA cloning of a novel metallothionein-like, cadmium-binding protein from Caenorhabditis elegans.

Caenorhabditis elegans adapted for survival in high concentrations of Cd(II) express a heavy metal binding protein designated C. elegans metallothionein-like protein or MT-Ce. This protein was purified to homogeneity and characterized. MT-Ce binds 6 mol of Cd(II)/mol protein. The sequence of 39 amino-terminal residues in MT-Ce was determined. A radiolabeled 41-mer oligonucleotide, designed from the partial MT-Ce sequence, was used in conjunction with sucrose gradient centrifugation to obtain size-fractionated poly(A+) RNA enriched in MT-Ce sequences. Subsequently, cloned cDNAs, corresponding to MT-Ce mRNA sequences, were isolated from a lambda ZapII cDNA library prepared from the enriched template mRNA. cDNA and protein sequence analysis revealed that MT-Ce comprises 62 amino acid residues and has a predicted Mr of 6462. Seventeen of the 18 Cys residues in the nematode cadmium-binding protein are included in Cys-X-Cys and X-Cys-Cys-X motifs that are characteristic of mammalian metallothioneins (MTs). However, the resemblance of MT-Ce to mammalian MTs is superficial. The amino acid sequence of MT-Ce is unique, and neither its putative alpha and beta domains nor its Cys residues can be readily aligned with the corresponding regions of other eukaryotic MTs. This suggests that MT-Ce is an example of convergent evolution. The MT-Ce mRNA level in nematodes that were selected and grown with Cd(II) concentrations that are lethal for wild-type worms, was 55-fold higher than the level of MT-Ce mRNA in wild-type C. elegans. Comparison of the sequences of MT-Ce cDNAs revealed the occurrence of two types of MT-Ce mRNA. Each contains an identical coding region, but the cDNAs diverge markedly in their 5'-untranslated regions. This suggests the possibilities of regulation by alternative splicing and/or the presence of multiple MT-Ce genes encoding a single protein, but controlled by different regulatory elements.

Intracellular copper transport in cultured hepatoma cells.

The distribution of copper in lysates prepared anaerobically from copper-resistant hepatoma cells radiolabeled with 67Cu was examined in pulse-chase experiments. Initially, the majority of the radioactivity (greater than 85%) coeluted with copper-metallothionein. As the chase time increased there was a gradual loss of 67Cu from metallothionein, with a concomitant increase in the level of 67Cu-labeled glutathione. There was also an increase in 67Cu incorporation into superoxide dismutase. These results suggest that the chelation of copper by metallothionein from a copper-glutathione complex (Freedman, J. H., Ciriolo, M. R., and Peisach, J. (1989) J. Biol. Chem. 264, 5598-5605) is a reversible process. Further, they demonstrate that the copper bound to metallothionein is not permanently sequestered, but can be incorporated into other copper proteins.

Resistance of cultured hepatoma cells to copper toxicity. Purification and characterization of the hepatoma metallothionein.

The mechanism of resistance to the toxic effects of copper was investigated using a series of copper-resistant hepatoma cell lines maintained in copper-enriched medium. Gel electrophoresis of carboxyamidated cell extracts demonstrated the presence of a pair of low molecular mass cysteine-rich proteins in wild-type and resistant cell lines. These proteins were purified to homogeneity and contained approx. 60% of the total cellular copper. Comparisons of molecular masses, pI values and amino-acid compositions for the purified hepatoma proteins with authentic rat liver metallothionein, as well as cross-reactivity with anti-rat metallothionein antibody, confirmed that the cysteine-rich hepatoma proteins were metallothioneins. The cellular concentration of these hepatoma copper-metallothioneins was proportional to both the level of metal resistance and the amount of copper accumulated by individual cell lines. Further, resistant cells removed from copper-enriched medium for 6-12 months, yet maintaining their level of resistance, showed only a slight decrease in metallothionein concentration. Thus it is proposed that the level of resistance to metal toxicity is mediated by the concentration of copper-metallothionein. It is also suggested that the steady-state level of copper metallothionein is controlled by the degree of metal exposure.

The role of glutathione in copper metabolism and toxicity.

Cellular copper metabolism and the mechanism of resistance to copper toxicity were investigated using a wild type hepatoma cell line (HAC) and a copper-resistant cell line (HAC600) that accumulates copper and has a highly elevated level of metallothionein (MT). Of the enzymes involved in reactive oxygen metabolism, only glutathionine peroxidase was elevated (3-4-fold) in resistant cells, suggestive of an increase in the cellular flux of hydrogen peroxide. A majority of the cytoplasmic copper (greater than 60%) was isolated from both cell lines as a GSH complex. Kinetic studies of 67Cu uptake showed that GSH bound 67Cu before the metal was complexed by MT. Depletion of cellular GSH with buthionine sulfoximine inhibited the incorporation of 67Cu into MT by greater than 50%. These results support a model of copper metabolism in which the metal is complexed by GSH soon after entering the cell. The complexed metal is then transferred to MT where it is stored. This study also indicates that resistance to metal toxicity in copper-resistant hepatoma cells is due to increases in both cellular GSH and MT. Furthermore, it is suggested that elevated levels of GSH peroxidase allows cells to more efficiently accommodate an increased cellular hydrogen peroxide flux that may occur as a consequence of elevated levels of cytoplasmic copper.

X-ray absorption spectroscopic study of the active copper sites in dopamine beta-hydroxylase.

X-ray absorption spectroscopy has been used to investigate the local environment of the copper sites in bovine dopamine beta-hydroylase, the enzyme that catalyzes the conversion of dopamine to norepinephrine in the adrenal medulla and noradrenergic nerve cells. The marked similarity of the x-ray absorption edge features of the oxidized and ascorbate-reduced forms of the enzyme with those of the corresponding Cu(imidazole)4 complexes suggests that the ligation in both cases is very similar. Furthermore, this similarity is found for the extended x-ray absorption fine structure data, and analysis shows only nitrogen (or oxygen) ligation for both enzyme forms. Thus, four nitrogen atoms provide the best fit to the data at an average distance of 1.97 +/- 0.02 A for the oxidized enzyme and four nitrogen atoms at 2.05 +/- 0.02 A for the ascorbate-reduced form. The present data analysis also indicates that there is little change in the average copper ligand environment upon reduction of the enzyme-bound copper from Cu(II) to the Cu(I). The data for the oxidized form of the enzyme are in agreement with previous spin-echo EPR experiments that show three to four imidazole nitrogen ligands for each copper (McCracken, J., Desai, P. R., Papadopoulos, N. J., Villafranca, J. J., and Peisach, J. (1988) Biochemistry 27, 4133-4137). In addition, the data do not indicate the presence of any heavy atom (sulfur or chlorine) ligation to the ascorbate-reduced form of the enzyme as reported by Scott et al. (Scott, R. A., Sullivan, R. J., DeWolf, W. E., Jr., Dolle, R. E., and Kruse, L. I. (1988) Biochemistry 27, 5411-5417).

Electron paramagnetic resonance and magnetic susceptibility studies of dimanganese concanavalin A. Evidence for antiferromagnetic exchange coupling.

The double Mn2+ complex of concanavalin A with bound saccharide (SMMPL) was examined by electron paramagnetic resonance (EPR) spectroscopy and magnetic susceptibility measurements. A room temperature X-band (9 GHz) EPR spectrum of SMMPL revealed a relatively weak, broad resonance in contrast to the spectrum with a six-line hyperfine-split pattern observed for the mononuclear, high-spin Mn2+ complex found in Ca2+-Mn2+-concanavalin A with saccharide present (SCMPL). The EPR spectrum of SMMPL at 77 K, however, consisted of a series of overlapping patterns of 11 hyperfine-split lines near g = 2.0 with members of each pattern separated by 47 G, half the value of the hyperfine splitting of SCMPL. These 11-line patterns are preserved at Q-band (35 GHz), indicating that the manganese ions in SMMPL form a spin-coupled, binuclear center. As expected for an exchange-coupled system, the EPR signal of SMMPL at 77 K saturates at a higher microwave power than those for SCMPL or Mn2+ aquoion. There is also a marked loss of EPR signal intensity for SMMPL between 4.2 and 1.4 K, which supports the view that the pair of manganese ions is exchanged-coupled. The temperature dependence of both the magnetic susceptibility and the low-temperature EPR spectral intensity can be explained by a model in which the two high-spin Mn2+ ions of SMMPL are antierromagnetically exchanged-coupled with an isotropic coupling constant J = 1.8 cm-1 (for the spin Hamiltonian Hex = JS1.S2). Zero-field splitting D' was estimated to be 375 G from the EPR spectrum.(ABSTRACT TRUNCATED AT 250 WORDS)