Monolithically integrated single quantum dots coupled to bowtie nanoantennas.

Deterministically integrating semiconductor quantum emitters with plasmonic nano-devices paves the way towards chip-scale integrable, true nanoscale quantum photonic technologies. For this purpose, stable and bright semiconductor emitters are needed, which moreover allow for CMOS-compatibility and optical activity in the telecommunication band. Here, we demonstrate strongly enhanced light-matter coupling of single near-surface (< 10 nm) InAs quantum dots monolithically integrated into electromagnetic hot-spots of sub-wavelength sized metal nanoantennas. The antenna strongly enhances the emission intensity of single quantum dots by up to ~ 16×, an effect accompanied by an up to 3.4× Purcell-enhanced spontaneous emission rate. Moreover, the emission is strongly polarised along the antenna axis with degrees of linear polarisation up to ~ 85 %. The results unambiguously demonstrate a pronounced coupling of individual quantum dots to state-of-the-art nanoantennas. Our work provides new perspectives for the realisation of quantum plasmonic sensors, step-changing photovoltaic devices, bright and ultrafast quantum light sources and efficient nano-lasers.

The prediction of disability by self-reported physical frailty components of the Tilburg Frailty Indicator (TFI).

Disability is an important health outcome for older persons; it is associated with impaired quality of life, future hospitalization, and mortality. Disability also places a high burden on health care professionals and health care systems. Disability is regarded as an adverse outcome of physical frailty. The main objective of this study was to assess the predictive validity of the eight individual self-reported components of the physical frailty subscale of the TFI for activities of daily living (ADL) and instrumental activities of daily living (IADL) disability. This longitudinal study was carried out with a sample of Dutch citizens. At baseline the sample consisted at 429 people aged 65 years and older and a subset of all respondents participated again two and a half years later (N=355, 83% response rate). The respondents completed a web-based questionnaire comprising the TFI and the Groningen Activity Restriction Scale (GARS) for measuring disability. Five components together (unintentional weakness, weakness, poor endurance, slowness, low physical activity), referring to the phenotype of Fried et al., predicted disability, even after controlling for previous disability and other background characteristics. The other three components of the physical frailty subscale of the TFI (poor balance, poor hearing, poor vision) together did not predict disability. Low physical activity predicted both total and ADL disability, and slowness both total and IADL disability. In conclusion, self-report assessment using the physical subscale of the TFI aids the prediction of future ADL and IADL disability in older persons two and a half years later.

Platinum(II)-based coordination compounds as nucleic acid labeling reagents: synthesis, reactivity, and applications in hybridization assays.

The synthesis, characterization, and molecular interactions of platinum(II) coordination compounds, which contain a distal nonradioactive reporter molecule, with mono- and polynucleotides are described. A [Pt(II)(en)(NH(2)(CH(2))(6)NH-tBoc)Cl](NO(3)) (en=ethylenediamine) entity has been coupled, after removal of the tBoc group, to a number of hapten and fluorophore molecules through succinimide derivatives. The influence of the various tethered reporter groups within these complexes on the reactivity towards guanosine 5'-monophosphate (5'-GMP), as a model for polynucleotide sequences, was investigated to shed light on the use of these reagents in hybridization assays. Reactivity turned out to be strongly dictated by the chemical nature of the distal reporter molecule present. At pH 7.0 the sequence of reactivity is cationic approximately aromatic (stacking) > neutral > anionic; there is approximately an order of magnitude difference between the fastest reacting complex (k=10.2 x 10(-2) M(-1) s(-1)) and the slowest reacting complex (k=0.93 x 10(-2) M(-1) s(-1)) under these conditions. Platination of an oligodeoxynucleotide (30-mer), dsDNA, or an RNA transcript, shows that a Pt/nucleotide ratio between 1:10 and 1:20 (established by using flameless atomic absorption spectroscopy) results in probes with excellent hybridization characteristics. In terms of applicability and detection limits these platinated nucleic acid probes perform equally well compared to conventionally generated nucleic acid probes, that is, through enzymatic incorporation of covalently labeled nucleotide triphosphates. Applications of these reagents to in situ hybridization assays and gene expression profiling on microarrays illustrate the potential of these monofunctional binding platinum triamine compounds.

Demonstration that menthofuran synthase of mint (Mentha) is a cytochrome P450 monooxygenase: cloning, functional expression, and characterization of the responsible gene.

(+)-Menthofuran is an undesirable monoterpenoid component of peppermint (Mentha x piperita) essential oil that is derived from the alpha,beta-unsaturated ketone (+)-pulegone. Microsomal preparations, from the oil gland secretory cells of a high (+)-menthofuran-producing chemotype of Mentha pulegium, transform (+)-pulegone to (+)-menthofuran in the presence of NADPH and molecular oxygen, implying that menthofuran is synthesized by a mechanism analogous to that of mammalian liver cytochrome P450s involving the hydroxylation of the syn-methyl group of (+)-pulegone, spontaneous intramolecular cyclization to the hemiketal, and dehydration to the furan. An abundant cytochrome P450 clone from a peppermint oil gland cell cDNA library was functionally expressed in Saccharomyces cerevisiae and Escherichia coli and shown to encode the (+)-menthofuran synthase (i.e., (+)-pulegone-9-hydroxylase). The full-length cDNA contains 1479 nucleotides, and encodes a protein of 493 amino acid residues of molecular weight 55,360, which bears all of the anticipated primary structural elements of a cytochrome P450 and most closely resembles (35% identity) a cytochrome P450 monoterpene hydroxylase, (+)-limonene-3-hydroxylase, from the same source. The availability of this gene permits transgenic manipulation of peppermint to improve the quality of the derived essential oil.

Hydroxylation of limonene enantiomers and analogs by recombinant (-)-limonene 3- and 6-hydroxylases from mint (Mentha) species: evidence for catalysis within sterically constrained active sites.

Limonene enantiomers and substrate analogs, including specifically fluorinated derivatives, were utilized to probe active site interactions with recombinant (-)-(4S)-limonene-3-hydroxylase (CYP71D13) and (-)-(4S)-limonene-6-hydroxylase (CYP71D18) from mint (Mentha) species. (-)-(4S)-Limonene is hydroxylated by both enzymes at the designated C3- and C6-allylic positions, with strict regio- and stereospecificity and without detectable allylic rearrangement, to give the corresponding products (-)-trans-isopiperitenol and (-)-trans-carveol. CYP71D13-catalyzed hydroxylation of (+)-(4R)-limonene also yields the corresponding trans-3-hydroxylated product ((+)-transisopiperitenol); however, the C6-hydroxylase converts (+)-(4R)-limonene to a completely different product profile dominated by the enantiopure cis-6-hydroxylated product (+)-cis-carveol along with several minor products, including both enantiomers of the trans-6-hydroxylated product ((+/-)-trans-carveol), indicating allylic rearrangement during catalysis. These results demonstrate that the regiospecificity and facial stereochemistry of oxygen insertion is dictated by the absolute configuration of the substrate. Fluorinated limonene analogs are also tightly bound by both enzymes and hydroxylated at the topologically congruent positions in spite of the polarizing effect of the fluorine atom on substrate reactivity. This strict retention of oxygenation geometry suggests a rigid substrate orientation imposed by multiple hydrophobic active site contacts. Structurally simplified substrate analogs are hydroxylated at slower rates and with substantial loss of regiospecificity, consistent with a loss of active site complementarity. Evaluation of the product profiles generated allowed assessment of the role of hydrophobic contacts in orienting the substrate relative to the activated oxygen species.

Binary typing of Staphylococcus aureus strains through reversed hybridization using digoxigenin-universal linkage system-labeled bacterial genomic DNA.

A novel binary typing (BT) procedure, based on reversed hybridization of digoxigenin-universal linkage system-labeled bacterial DNA to strip-immobilized probes, is presented. Chromogenic detection of hybrids was performed. Staphylococcus aureus isolates (n = 20) were analyzed to establish the feasibility of BT. A technically simple and fast procedure has been developed for application in routine microbiology laboratories.

A single amino acid substitution (F363I) converts the regiochemistry of the spearmint (-)-limonene hydroxylase from a C6- to a C3-hydroxylase.

The essential oils of peppermint and spearmint are distinguished by the position of oxygenation on the constituent p-menthane monoterpenes. Peppermint produces monoterpenes bearing an oxygen at C3, whereas spearmint produces monoterpenes bearing an oxygen at C6. Branching of the monoterpene biosynthetic pathways in these species is determined by two distinct cytochrome P450s that catalyze the regiospecific hydroxylation of (-)-4S-limonene at C3 or C6 exclusively. cDNAs encoding the limonene-3-hydroxylase from peppermint and the limonene-6-hydroxylase from spearmint have been isolated, shown to be 70% identical at the amino acid level, and functionally expressed. A combination of domain swapping and reciprocal site-directed mutagenesis between these two enzymes demonstrated that the exchange of a single residue (F363I) in the spearmint limonene-6-hydroxylase led to complete conversion to the regiospecificity and catalytic efficiency of the peppermint limonene-3-hydroxylase.

Functional expression of regiospecific cytochrome P450 limonene hydroxylases from mint (Mentha spp.) in Escherichia coli and saccharomyces cerevisiae.

The oxygenation pattern of the essential oil monoterpenes of commercial mint (Mentha) species is determined by regiospecific cytochrome P450-catalyzed hydroxylation of the common olefinic precursor (-)-4S-limonene. In spearmint (M. spicata), C6-allylic hydroxylation leads to (-)-trans-carveol and thence (-)-carvone, whereas in peppermint (M. x piperita), C3-allylic hydroxylation leads to (-)-trans-isopiperitenol and ultimately (-)-menthol. cDNAs encoding the C6-hydroxylase and C3-hydroxylase from spearmint and peppermint, respectively, were isolated by a combination of reverse genetic and homology-based cloning methods (S. Lupien, F. Karp, M. Wildung, and R. Croteau, Arch. Biochem. Biophys. 368, 181-192, 1999). Although both hydroxylase genes were confirmed by functional expression using the baculovirus-Spodoptera system, too little protein was available by this approach to permit detailed study of the structure-function relationships of these catalysts, especially the substrate binding determinants that underlie the regiochemistry and stereochemistry of the reactions. Therefore, heterologous overexpression systems based on Escherichia coli and Saccharomyces cerevisiae were developed to produce several N-terminally modified versions of the recombinant hydroxylases. Ancillary methods for the solubilization, purification, and reconstitution (with recombinant spearmint cytochrome P450 reductase) of the limonene hydroxylases were also devised, with which substrate binding behavior and precise regiochemistry and stereochemistry of product formation were determined.

Increasing expression of P450 and P450-reductase proteins from monocots in heterologous systems.

Monocotyledonous crop plants are usually more resistant to herbicides than grass weeds and most dicots. Their resistance to herbicides is mediated in many cases by P450 oxygenases. Monocots thus constitute an appealing source of P450 enzymes for manipulating herbicide resistance and recombinant forms of the major xenobiotic metabolizing mooxygenases are potential tools for the optimization of new active molecules. We report here the isolation and functional characterization of the first P450 and P450 reductase coding sequences from wheat. The first attempts at expressing these cDNAs in yeast and tobacco led to levels of protein, which were extremely low, often not even detectable. The wheat P450 cDNAs were efficiently transcribed, but no protein or activity was found. Wheat coding sequences, like those of other monocots, are characterized by a high GC content and by a related strong bias of codon usage, different from that observed in yeast or dicots. Complete recoding of genes being costly, the reengineering their 5'-end using a single PCR megaprimer designed to comply with codon usage of the host was attempted. It was sufficient to relieve translation inhibition and to obtain good levels of protein expression. The same strategy also resulted in a dramatic increase in protein expression in tobacco. A basis for the success of such a partial recoding strategy, much easier and cheaper than complete recoding of the cDNA, is proposed.

Novel characteristics and regulation of a divergent cinnamate 4-hydroxylase (CYP73A15) from French bean: engineering expression in yeast.

cDNAs showing high sequence similarity (>70%) over large stretches to plant CYP73A orthologues from other species were isolated from a cDNA library derived from mRNAs expressed in elicitor-treated suspension-cultured cells. These clones appear to code for a full-length 1554 bp open reading frame with a 78 bp 5'-untranslated region and a 140 bp 3'-untranslated region. The open reading frame, determined by sequence similarity, codes for a protein with a predicted Mr of 59229 and a pI of 8.8. It contains the conserved cysteine haem-binding site found in all cytochrome P450s. The protein encoded by this cDNA diverges however from other CYP73As in its N- and C-terminus and in four domains internally, so that overall sequence similarity is in the range 58-66%. Many clones contained an identical intron, which may be associated with a novel regulatory mechanism. Sequence similarity is sufficient for it to be classified as CYP73A15, although it is the least similar member of this family classified so far. The cDNA was expressed in yeast. Successful expression of cinnamate 4-hydroxylase activity required removal of the intron. High-level expression also required modification of the N-terminus to that of CYP73A1. Yeast did not process the intron at all and the leader sequence for A15 was not as compatible as that of A1. The mRNA for CYP73A15 was shown to be rapidly induced by elicitor treatment of suspension-cultured cells of French bean but induction was more transient than that of phenylalanine ammonia-lyase (PAL). In contrast, induction in cells undergoing xylogenesis was much more coordinate with PAL. The cloned cDNA may represent a cinnamate 4-hydroxylase isoform, whose expression is more related to differentiation than the responses to stress in which the majority of CYP73As cloned so far are involved.

Role of unusual amino acid residues in the proximal and distal heme regions of a plant P450, CYP73A1.

CYP73A1 is a typical plant P450 in terms of its function and primary sequence. The enzyme catalyzes the 4-hydroxylation of trans-cinnamic acid, the first oxidative step in the phenylpropanoid pathway. Its primary protein sequence exhibits some particular landmarks which are characteristic of plant P450 enzymes. The most interesting is a proline residue (Pro448), very unusual in animal P450s, just C-terminal to the invariant heme-binding cysteine. To determine the role of this proline, we substituted it with valine, isoleucine, or phenylalanine, residues found in animal P450s, using site-directed mutagenesis. Expression of the wild type and mutants in yeast indicated that replacement of Pro448 led to disruption of the heme-protein interaction, loss of catalytic activity, and either impaired expression or destabilization of the apoprotein. Pro448 is thus essential for the correct insertion of heme in the apoprotein. Another typical feature of CYP73A proteins is the presence of an alanine-alanine motif (Ala306-Ala307) on the presumed N-terminal edge of the cleft in the central part of the I helix. This cleft faces the iron on the distal side of the heme and is proposed to be essential for catalysis. Substitution of each or both Ala306 and Ala307 residues with glycines showed that they are critical for the stability of the protein and influence the positioning of the substrate in the active site. Results are discussed with reference to the structural X-ray data that are available for bacterial P450 proteins.

Piperonylic acid, a selective, mechanism-based inactivator of the trans-cinnamate 4-hydroxylase: A new tool to control the flux of metabolites in the phenylpropanoid pathway

Piperonylic acid (PA) is a natural molecule bearing a methylenedioxy function that closely mimics the structure of trans-cinnamic acid. The CYP73A subfamily of plant P450s catalyzes trans-cinnamic acid 4-hydroxylation, the second step of the general phenylpropanoid pathway. We show that when incubated in vitro with yeast-expressed CYP73A1, PA behaves as a potent mechanism-based and quasi-irreversible inactivator of trans-cinnamate 4-hydroxylase. Inactivation requires NADPH, is time dependent and saturable (KI = 17 &mgr;M, kinact = 0.064 min-1), and results from the formation of a stable metabolite-P450 complex absorbing at 427 nm. The formation of this complex is reversible with substrate or other strong ligands of the enzyme. In plant microsomes PA seems to selectively inactivate the CYP73A P450 subpopulation. It does not form detectable complexes with other recombinant plant P450 enzymes. In vivo PA induces a sharp decrease in 4-coumaric acid concomitant to cinnamic acid accumulation in an elicited tobacco (Nicotiana tabacum) cell suspension. It also strongly decreases the formation of scopoletin in tobacco leaves infected with tobacco mosaic virus.

Molecular cloning and functional expression in yeast of CYP76B1, a xenobiotic-inducible 7-ethoxycoumarin O-de-ethylase from Helianthus tuberosus.

In order to obtain plant markers of chemical stress and possible tools for the bio-monitoring of pollution, a protein purification/PCR approach was used to isolate cDNAs of xenobiotic-inducible P450 oxygenases. O-dealkylation of 7-ethoxycoumarin is catalysed in Helianthus tuberosus by cytochromes P450 strongly inducible by a wide range of xenobiotics. Therefore, a 7-ethoxycoumarin O-de-ethylase (ECOD) was purified from induced tuber tissues (Batard et al., 1995). A primer designed from an internal peptide sequence, but also corresponding to a conserved P450 haem-binding region, led to the generation of a gene-specific probe corresponding to a P450 strongly inducible by aminopyrine. Two partial and 98% identical coding sequences were isolated from a cDNA library prepared from aminopyrine-induced tuber. A full-length cDNA was reconstituted by 5'-RACE elongation. The protein deduced from this full-length sequence, with 41.1% amino acid identity to CYP76A1 and high phylogenetic relationship to other CYP76s, was termed CYP76B1. CYP76B1 was expressed in yeast. Microsomes from the transformed yeast catalysed the NADPH-dependent O-dealkylation of 7-ethoxycoumarin. However, protein sequence as well as enzymological data indicated that CYP76B1 does not correspond to the purified ECOD protein. These results confirm previous data and demonstrate that several P450s in H. tuberosus are capable of actively catalysing the O-de-ethylation of ethoxycoumarin. Determination of the steady-state level of CYP76B1 transcripts after slicing tuber tissues and ageing them in water, alone or in the presence of various chemicals, showed that the expression of this P450 was not responsive to mechanical stress, but was strongly induced by chemical treatments. CYP76B1 thus appears to be a good potential marker of chemical stress and of environmental pollution.

Regulation of the Cinnamate 4-Hydroxylase (CYP73A1) in Jerusalem Artichoke Tubers in Response to Wounding and Chemical Treatments.

trans-Cinnamate 4-hydroxylase (C4H) is a plant-specific cytochrome (P450) that is encoded by the gene CYP73A and catalyzes the second step of the multibranched phenylpropanoid pathway. Increases in C4H activity in response to physical and chemical stresses have been well documented, but the mechanism of these increases has never been studied in detail. This paper reports on the regulatory mechanism controlling C4H activity in Jerusalem artichoke (Helianthus tuberosus) tubers in response to wounding and chemical treatments. We compared induction of C4H and other P450-catalyzed activities. C4H was moderately induced by chemicals relative to other P450s. Increases in enzyme activity, C4H protein, and transcripts were quantified and compared in tuber tissue 48 h after wounding and chemical treatments. Our data suggest that induction of the enzyme activity results primarily from gene activation. Time-course experiments were performed after wounding and aminopyrine treatment. Compared with wounded tissues, aminopyrine triggered an additional and delayed peak of transcript accumulation. The timing of the induced changes in activity, protein, and transcripts confirms that C4H induction results primarily from an increase in CYP73A1 mRNA, in both wounded and aminopyrine-treated tissues. However, posttranscriptional mechanisms might also contribute to the regulation of C4H activity.

Xenobiotics: Substrates and inhibitors of the plant cytochrome P450.

The ability of a plant cytochrome P450 to bind and metabolise plant endogenous molecules and xenobiotics was investigated. The work was performed on the yeast-expressed CYP73A1, a cinnamate 4-hydroxylase isolated from Helianthus tuberosus. CYP73 controls the general phenylpropanoid pathway and is likely to be one of the most abundant sources of P450 in the biosphere. The enzyme shows a high selectivity toward plant secondary metabolites. Nevertheless, it oxygenates several small and planar xenobiotics with low efficiency, including an herbicide (chlorotoluron). One xenobiotic molecule, 2-naphthoic acid, is hydroxylated with an efficiency comparable to that of the physiological substrate. This reaction was used to devise a fluorimetric test for the rapid measurement of enzyme activity. A series of herbicidal molecules (hydroxybenzonitriles) are shown to bind the active site without being metabolised. These molecules behave as strong competitive inhibitors of CYP73 with a K(i) in the same micromolar range as the K(m) for the physiological substrate. It is proposed that their inhibition of the phenylpropanoid pathway reinforces their other phytotoxic effects at the level of the chloroplasts. All our results indicate a strong reciprocal interaction between plant P450s and xenobiotics.

Design of fluorescent substrates and potent inhibitors of CYP73As, P450s that catalyze 4-hydroxylation of cinnamic acid in higher plants.

CYP73As are the major functional cytochromes P450 in higher plants. Several of them have been shown to catalyze the 4-hydroxylation of cinnamic acid, the first oxidative step in the synthesis of lignin, flavonoids, coumarins, and other phenylpropanoids. The coding sequence for CYP73A1, the enzyme from Helianthus tuberosus, has been isolated and expressed in yeast. Previous studies indicate that the yeast-expressed enzyme is capable of metabolizing cinnamic acid and several small, planar molecules but with low efficiency. Using this we further examined how CYP73A1 could bind and metabolize a set of possible alternate substrates. We show here that naphthalenes, quinolines, and indoles substituted with an aldehyde, a carboxylic, or a sulfonic acid group make good ligands and substrates for CYP73A1. The best ligands are hydroxynaphthoic acids, which show higher affinity than cinnamate. Naphthalene, 2-naphthol, and molecules with two-carbon side chains, such as natural and synthetic auxins, are not substrates of this enzyme. Methyl-2-naphthoate and 2-hydroxy-1-naphthoic acid are strong ligands of CYP73A1 but are not metabolized. Uncoupling and low spin conversion induced by these compounds suggest that their positioning in the heme pocket is inadequate for catalysis. These compounds can act as potent inhibitors of the second step of the phenylpropanoid pathway, the first described so far. The molecule which most closely mimics cinnamic acid, 2-naphthoic acid, is metabolized with a catalytic turnover and efficiency similar to those measured with the physiological substrate. Using this compound we designed a fluorometric assay to measure the catalytic activity of CYP73As. This assay was then used to monitor the CYP73As activity in microsomes from transgenic yeast and several plant species.

Species-specific antagonism of Ah receptor action by 2,2',5,5'-tetrachloro- and 2,2',3,3'4,4'-hexachlorobiphenyl.

Using recombinant cell lines showing Ah receptor-controlled expression of a luciferase reporter gene, the interaction of di-ortho-substitute polychlorinated biphenyls (PCBs) with Ah receptor agonists was studied. In the recombinant Hepa1c1c7 mouse hepatoma (H1L1.1c7) cells strong antagonistic interaction of 2,2',5,5'-tetrachlorobiphenyl (PCB52) with luciferase expression induced by 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD) or 3,3',4,4'-tetrachlorobiphenyl (PCB77) was observed, and similarly, between 2,2',3,3',4,4'-hexachlorobiphenyl (PCB128) and PCB77. Accordingly, PCB52 was found to inhibit ethoxyresorufin-O-deethylase (EROD) induction by PCB77 in wild-type Hepa1c1c7 cells. In contrast, the antagonistic effect of PCB52 on TCDD-induced luciferase expression was only minor in recombinant guinea pig GPC16 colon adenocarcinoma (G16L1.1c8) and human HepG2 hepatoma (HG2L1.1c3) cells, and intermediate in recombinant H4IIE rat hepatoma (H4L1.1c4) cells. Gel retardation studies using a 32 P-labelled dioxin responsive element (DRE)-containing oligonucleotide, and ligand binding studies using [3H]TCDD, demonstrated that the species-specific antagonistic activity of PCB52 on Ah receptor-controlled luciferase expression is due to inhibition of Ah receptor ligand and DNA binding. We conclude, that Ah-mediated luciferase expression provides a useful tool to study the species specificity of Ah receptor (ant)agonists.

Stress factors that can affect studies of drug metabolism in fish.

The effects of environmental stress conditions on the defense response of rainbow trout following a four week exposure to subacute levels of un-ionized ammonia or temperatures 5 C above and 5 C below the temperature optimum (15 C) were investigated. These experimental studies can serve as a model to evaluate the metabolic response of fish to external agents (e.g., drugs, vaccines) under environmental conditions seen in the culture of fish. Blood and tissue immune parameters measured include hematocrits, antibody levels and differentiation of white blood cell populations in tissue imprints of the anterior kidney. These analyses were compared to the growth parameter, average percent weight gain. Fish given primary and secondary immunization with a bacterial vaccine (Aeromonas hydrophila) were exposed to sublethal concentrations of un-ionized ammonia of 0.2, 0.3 or 0.4 mg/ml. Fish exposed to the higher concentrations of ammonia showed a decrease in growth compared to control fish. Several significant changes were observed in the leukocytes of the anterior kidney at the various concentrations of ammonia tested. A decrease in antibody titers to A hydrophila was seen at the two higher concentrations of ammonia. In a second study, the effects of non-optimum temperature conditions (10 C and 20 C) were compared with an optimum temperature (15 C). Fish held at sub-optimum temperatures had significantly lower hematocrits than the control fish maintained at 15 C. Several significant changes were also seen in the anterior kidney leukocytes. Antibody titers to A hydrophila were significantly lower at the end of the stressing period in the trout maintained at 10 C compared to the immunized controls at 15 C. In contrast, fish held at 20 C had significantly higher antibody titers than did the immunized controls. Compared to controls, fish growth was increased at 10 C and decreased at 20 C. These studies confirm that environmental factors can induce stress and affect the metabolism and health of the fish.