橙色荧光蛋白——绿色荧光蛋白GFPxm的改造

最近报道了从大型多管水母中分离出新的gfp基因。经大肠杆菌表达并纯化出的绿色荧光蛋白 (GFPxm)具有 4 76nm的激发峰和 4 96nm的发射峰 ,但是只能在低温下成熟的缺点限制了它的应用。这里进一步报道GFPxm的 12种突变型。在大肠杆菌中的表达结果表明 ,有 7种突变型在 37℃条件下产生高的荧光强度。在 2 5、32和 37℃条件下表达 6h ,GFPxm16、GFPxm18和GFPxm19的相对荧光强度均高于增强型绿色荧光蛋白 (EGFP) ,而GFPxm16和GFPxm16 3在 4 2℃高温表达时仍能保持高的荧光强度。这 7种突变型中的 4种在哺乳动物细胞中已获得良好表达。此外 ,有 6种突变型的荧光光谱红移 ,目前所达到的最长激发峰为 5 14nm、最长发射峰为 5 2 5nm。另外有 3种突变型具有包括紫外在内的两个激发峰 ,1种突变型只有单一的紫外激发峰。首次报道具有橙色荧光的突变型OFPxm ,它的激发峰为 5 0 9nm、发射峰为 5 2 3nm。 5 2 3nm属于黄绿色 ,但肉眼看到的蛋白为橙色。OFPxm在高温下可得到高水平表达且很好地成熟 ,但是因为低的量子产率而荧光强度相对较低。     

Enhanced fluorescent properties of an OmpT site deleted mutant of Green Fluorescent Protein

Background  

The green fluorescent protein has revolutionized many areas of cell biology and biotechnology since it is widely used in determining gene expression and for localization of protein expression. Expression of recombinant GFP in E. coli K12 host from pBAD24M-GFP construct upon arabinose induction was significantly lower than that seen in E. coli B cells with higher expression at 30°C as compared to 37°C in E. coli K12 hosts. Since OmpT levels are higher at 37°C than at 30°C, it prompted us to modify the OmpT proteolytic sites of GFP and examine such an effect on GFP expression and fluorescence. Upon modification of one of the two putative OmpT cleavage sites of GFP, we observed several folds enhanced fluorescence of GFP as compared to unmodified GFPuv (Wild Type-WT). The western blot studies of the WT and the SDM II GFP mutant using anti-GFP antibody showed prominent degradation of GFP with negligible degradation in case of SDM II GFP mutant while no such degradation of GFP was seen for both the clones when expressed in BL21 cells. The SDM II GFP mutant also showed enhanced GFP fluorescence in other E. coli K12 OmpT hosts like E. coli JM109 and LE 392 in comparison to WT GFPuv. Inclusion of an OmpT inhibitor, like zinc with WT GFP lysate expressed from an E. coli K12 host was found to reduce degradation of GFP fluorescence by two fold.     

Temperature influence on fluorescence intensity and enzyme activity of the fusion protein of GFP and hyperthermophilic xylanase

By constructing the expression system for fusion protein of GFPmut1 (a green fluorescent protein mutant) with the hyperthermophilic xylanase obtained from Dictyoglomus thermophilum Rt46B.1, the effects of temperature on the fluorescence of GFP and its relationship with the activities of GFP-fused xylanase have been studied. The fluorescence intensities of both GFP and GFP-xylanase have proved to be thermally sensitive, with the thermal sensitivity of the fluorescence intensity of GFP-xylanase being 15% higher than that of GFP. The lost fluorescence intensity of GFP inactivated at high temperature of below 60°C in either single or fusion form can be completely recovered by treatment at 0°C. By the fluorescence recovery of GFP domain at low temperature, the ratios of fluorescence intensity to xylanase activity (R _gfp/A _xyl) at 15°C and 37°C have been compared. Even though the numbers of molecules of GFP and xylanase are equivalent, the R _gfp/A _xyl ratio at 15°C is ten times of that at 37°C. This is mainly due to the fact that lower temperature is more conducive to the correct folding of GFP than the hyperthermophilic xylanase during the expression. This study has indicated that the ratio of GFP fluorescence to the thermophilic enzyme activity for the fusion proteins expressed at different temperatures could be helpful in understanding the folding properties of the two fusion partners and in design of the fusion proteins.     

Mutations that suppress the thermosensitivity of green fluorescent protein

Background The green fluorescent protein (GFP) of the jellyfish Aequorea victoria has recently attracted great interest as the first example of a cloned reporter protein that is intrinsically fluorescent. Although successful in some organisms, heterologous expression of GFP has not always been straight forward. In particular, expression of GFP in cells that require incubation temperatures around 37°C has been problematic.Results We have carried out a screen for mutant forms of GFP that fluoresce more intensely than the wild-type protein when expressed in E. coli at 37°C. We have characterized a bright mutant (GFPA) with reduced sensitivity to temperature in both bacteria and yeast, and have shown that the amino acids substituted in GFPA act by preventing temperature-dependent misfolding of the GFP apoprotein. We have shown that the excitation and emission spectra of GFPA can be manipulated by site-directed mutagenesis without disturbing its improved folding characteristics, and have produced a thermostable folding mutant (GFP5) that can be efficiently excited using either long-wavelength ultraviolet or blue light. Expression of GFP5 results in greatly improved levels of fluorescence in both microbial and mammalian cells cultured at 37°C.Conclusions The thermotolerant mutants of GFP greatly improve the sensitivity of the protein as a visible reporter molecule in bacterial, yeast and mammalian cells. The fluorescence spectra of these mutants can be manipulated by further mutagenesis without deleteriously affecting their improved folding characteristics, so it may be possible to engineer a range of spectral variants with improved tolerance to temperature. Such a range of sensitive reporter proteins will greatly improve the prospects for GFP-based applications in cells that require relatively high incubation temperatures.     

Characterization of Novel Orange Fluorescent Protein Cloned from Cnidarian Tube Anemone <Emphasis Type="Italic">Cerianthus</Emphasis> sp.

A novel orange fluorescent protein (OFP) was cloned from the tentacles of Cnidarian tube anemone Cerianthus sp. It consists of 222 amino acid residues with a calculated molecular mass of 25.1 kDa. A BLAST protein sequence homology search revealed that native OFP has 81% sequence identity to Cerianthus membranaceus green fluorescent protein (cmFP512), 38% identity to Entacmaea quadricolor red fluorescent protein (eqFP611), 37% identity to Discosoma red fluorescent protein (DsRed), 36% identity to Fungia concinna Kusabira-orange fluorescent protein (KO), and a mere 21% identity to green fluorescent protein (GFP). It is most likely that OFP also adopts the 11-strand β-barrel structure of fluorescent proteins. Spectroscopic analysis indicated that it has a wide absorption spectrum peak at 548 nm with two shoulders at 487 and 513 nm. A bright orange fluorescence maximum at 573 nm was observed when OFP was excited at 515 nm or above. When OFP was excited well below 515 nm, a considerable amount of green emission maximum at 513 nm was also observed. It has a fluorescence quantum yield (Φ) of 0.64 at 25°C. The molar absorption coefficients (ɛ) of folded OFP at 278 and 548 nm are 47,000 and 60,000 M-1⁻¹ • cm-1⁻¹, respectively. Its fluorescent brightness (ɛ Φ) at 25°C is 38,400 M⁻¹-1 • cm⁻¹-1. Like other orange-red fluorescent proteins, OFP is also tetrameric. It was readily expressed as soluble protein in Escherichia coli at 37°C, and no aggregate was observed in transfected HeLa cells under our experimental conditions. Fluorescent intensity of OFP is detectable over a pH range of 3 to 12.     

Two temperature-sensitive photosystem II mutants of pea

Two nuclear gene mutants of pea, chlorotica-887 and chlorina-5756, are temperature-sensitive in the development of photosystem II activity. Low temperature flourescence emission spectra of leaves show that the peak at 697 nm from the reaction center of photosystem II is present when the mutants have been grown at 18°C, but absent when they have been grown at 30°C. For leaves of chlorina-5756 grown at 18°C the relative size of the peak at 697 nm is reduced compared to that of leaves of the wild type or chlorotica-887 grown at this temperature. Flourescence induction curves of leaves from wild type plants and chlorotica-887 grown at 18°C possess two steps, while those of leaves from chlorina-5756 grown at 18°C or 30°C and chlorotica-887 grown at 30°C show at fast rise to the maximal level of fluorescence. Measurements on chloroplasts isolated from the mutants indicated that the photosystem I activity per g leaf material is comparable for plants grown at 18°C and plants grown at 30°C. In contrast, no photosystem II activity was detected when the mutants had been grown at 30°C. It is suggested that these mutants are affected in a component required for the assembly of functional photosystem II complexes.     

Appraisal of green fluorescent protein as a model substrate for seryl-histidine dipeptide cleaving agent

Summary We have investigated the action of seryl-histidine dipeptide (SH) on Green Fluorescent Protein (GFPxm) by SDS-PAGE and fluorescence techniques. It was found that 1 mmol SH showed a 75 units protease K (PK)-like cleavage effect at 50°C, pH 6.5–7.5. Compared with the results of SH cleavage on BSA, SDS-PAGE experiments showed no obvious fragments resulting from SH cleavage of GFPxm. SH quenched the GFPxm fluorescence greatly prior to cleavage. When the SH concentration reached 150 mM, the fluorescence quenching phenomena stopped. Compared cleavage. When the SH concentration reached 150 mM, the fluorescence quenching phenomena stopped. Compared with seryl-histidine dipeptide, the individual amino acids Ser and His, and these two amino acids mixed together, showed no effects on the spectral characteristics of GFPxm nor cleavage of GFPxm. Further study of the SH protein cleavage mechanism might provide insight for protease mechanisms and biomacromolecule evolution.     

Effect of polyethylene glycol on the thermal stability of green fluorescent protein

Green fluorescent protein (GFP) shows remarkable structural stability and high fluorescence; its stability can be directly related to its fluorescence output, among other characteristics. GFP is stable under increasing temperatures, and its thermal denaturation is highly reproducible. Some polymers, such as polyethylene glycol, are often used as modifiers of characteristics of biological macromolecules, to improve the biochemical activity and stability of proteins or drug bioavailability. The aim of this study was to evaluate the thermal stability of GFP in the presence of different PEG molar weights at several concentrations and exposed to constant temperatures, in a range of 70–95°C. Thermal stability was expressed in decimal reduction time. It was observed that the D‐values obtained were almost constant for temperatures of 85, 90, and 95°C, despite the PEG concentration or molar weight studied. Even though PEG can stabilize proteins, only at 75°C, PEG 600 and 4,000 g/mol stabilized GFP. © 2009 American Institute of Chemical Engineers Biotechnol. Prog., 2010     

Interactions between Escherichia coli and the plant‐parasitic nematode Meloidogyne javanica

Aims: To determine the potential of the plant‐parasitic nematode Meloidogyne javanica to serve as a temporary reservoir for Escherichia coli. Methods and Results: The adhesion to and persistence of E. coli on the surface of M. javanica were evaluated at different times and temperatures. A pure culture of green fluorescent protein (GFP) tagged E. coli was mixed with ca. 1000 J2 M. javanica for 2 h at 25°C. The nematodes were then washed and the rate of the adhesion of the bacteria to the nematodes was determined by counting the viable nematode‐associated E. coli, and by fluorescence microscopy. A dose‐dependent adhesion rate was observed only at a bacterium to nematode ratio of 10⁴–10⁶ : 1. The adhesion of E. coli to the nematodes was also tested over a 24 h‐period at 4°C, 25°C and 37°C. At 4°C and 37°C, maximal adhesion was observed at 5 h; whereas at 25°C, maximal adherence was observed at 8 h. Survival experiments showed that the bacteria could be detected on the nematodes for up to 2 weeks when incubated at 4°C and 25°C, but not at 37°C. Conclusions: Under laboratory conditions, at 4°C and 25°C, M. javanica could serve as a temporary vector for E. coli for up to 2 weeks. Significance and Impact of the Study: These findings support the hypothesis that, in the presence of high concentrations of E. coli, M. javanica might serve as a potential vehicle for the transmission of food‐borne pathogens.     

A variant of yellow fluorescent protein with fast and efficient maturation for cell-biological applications.

The green fluorescent protein (GFP) from the jellyfish Aequorea victoria has provided a myriad of applications for biological systems. Over the last several years, mutagenesis studies have improved folding properties of GFP (refs 1,2). However, slow maturation is still a big obstacle to the use of GFP variants for visualization. These problems are exacerbated when GFP variants are expressed at 37 degrees C and/or targeted to certain organelles. Thus, obtaining GFP variants that mature more efficiently is crucial for the development of expanded research applications. Among Aequorea GFP variants, yellow fluorescent proteins (YFPs) are relatively acid-sensitive, and uniquely quenched by chloride ion (Cl-). For YFP to be fully and stably fluorescent, mutations that decrease the sensitivity to both pH and Cl- are desired. Here we describe the development of an improved version of YFP named "Venus". Venus contains a novel mutation, F46L, which at 37 degrees C greatly accelerates oxidation of the chromophore, the rate-limiting step of maturation. As a result of other mutations, F64L/M153T/V163A/S175G, Venus folds well and is relatively tolerant of exposure to acidosis and Cl-. We succeeded in efficiently targeting a neuropeptide Y-Venus fusion protein to the dense-core granules of PC12 cells. Its secretion was readily monitored by measuring release of fluorescence into the medium. The use of Venus as an acceptor allowed early detection of reliable signals of fluorescence resonance energy transfer (FRET) for Ca2+ measurements in brain slices. With the improved speed and efficiency of maturation and the increased resistance to environment, Venus will enable fluorescent labelings that were not possible before.     

Citrate and phosphate influence on green fluorescent protein thermal stability

Protein structure and function can be regulated by no specific interactions, such as ionic interactions in the presence of salts. Green fluorescent protein (GFP) shows remarkable structural stability and high fluorescence; its stability can be directly related to its fluorescence output, among other characteristics. GFP is stable under increasing temperatures, and its thermal denaturation is highly reproducible. The aim of this study was to evaluate the thermal stability of GFP in the presence of different salts at several concentrations and exposed to constant temperatures, in a range of 70–95°C. Thermal stability was expressed in decimal reduction time. It was observed that the D‐values obtained were higher in the presence of citrate and phosphate, when compared with that obtained in their absence, indicating that these salts stabilized the protein against thermal denaturation. © 2010 American Institute of Chemical Engineers Biotechnol. Prog., 2011     

Red fluorescent protein from Discosoma as a fusion tag and a partner for fluorescence resonance energy transfer

The biochemical and biophysical properties of a red fluorescent protein from a Discosoma species (DsRed) were investigated. The recombinant DsRed expressed in E. coli showed a complex absorption spectrum that peaked at 277, 335, 487, 530, and 558 nm. Excitation at each of the absorption peaks produced a main emission peak at 583 nm, whereas a subsidiary emission peak at 500 nm appeared with excitation only at 277 or 487 nm. Incubation of E. coli or the protein at 37 degrees C facilitated the maturation of DsRed, resulting in the loss of the 500-nm peak and the enhancement of the 583-nm peak. In contrast, the 500-nm peak predominated in a mutant DsRed containing two amino acid substitutions (Y120H/K168R). Light-scattering analysis revealed that DsRed proteins expressed in E. coli and HeLa cells form a stable tetramer complex. DsRed in HeLa cells grown at 37 degrees C emitted predominantly at 583 nm. The red fluorescence was imaged using a two-photon laser (Nd:YLF, 1047 nm) as well as a one-photon laser (He:Ne, 543.5 nm). When fused to calmodulin, the red fluorescence produced an aggregation pattern only in the cytosol, which does not reflect the distribution of calmodulin. Despite the above spectral and structural complexity, fluorescence resonance energy transfer (FRET) between Aequorea green fluorescent protein (GFP) variants and DsRed was achieved. Dynamic changes in cytosolic free Ca2+ concentrations were observed with red cameleons containing yellow fluorescent protein (YFP), cyan fluorescent protein (CFP), or Sapphire as the donor and RFP as the acceptor, using conventional microscopy and one- or two-photon excitation laser scanning microscopy. Particularly, the use of the Sapphire-DsRed pair rendered the red cameleon tolerant of acidosis occurring in hippocampal neurons, because both Sapphire and DsRed are extremely pH-resistant.     

The construction of bifunctional fusion proteins consisting of MutS and GFP

MutS as a mismatch binding protein is a promising tool for SNP detection. Green fluorescent protein (GFP) is known as an excellent reporter domain. We constructed chimeric proteins consisting of MutS from Thermus thermophilus and GFPuv from Aequorea victoria by cloning the GFPuv gene into the plasmid vectors carrying the mutS gene. The GFPuv domain fused to the N-terminus of MutS (histag-GFP-MutS) exhibited the same level of green fluorescence as free GFPuv. To obtain the fluorescing histag-GFP-MutS protein the expression at 30 degrees C was required, while free GFPuv fluoresces when expressed both at 30 and 37 degrees C. The chimeric protein where the GFPuv domain was fused to the C-terminus of MutS exhibited much weaker green fluorescence (20-25% compared with those of histag-GFP-MutS or free GFPuv). The insertion of (ProGly)5 peptide linker between the MutS and GFP domains resulted in no significant improvement in GFP fluorescence. No shifts in the excitation and emission spectra have been observed for the GFP domain in the fusion proteins. The fusion proteins with GFP at the N- and C-terminus of MutS recognised DNA mismatches similarly like T. thermophilus MutS. The fluorescent proteins recognising DNA mismatches could be useful for SNP scanning or intracellular DNA analysis. The fusion proteins around 125 kDa were efficiently expressed in E. coli and purified in milligram amounts using metal chellate affinity chromatography.     

UBQLN2 undergoes a reversible temperature-induced conformational switch that regulates binding with HSPA1B: ALS/FTD mutations cripple the switch but do not destroy HSPA1B binding

Here we present evidence, based on alterations of its intrinsic tryptophan fluorescence, that UBQLN2 protein undergoes a conformational switch when the temperature is raised from 37 °C to 42 °C. The switch is reset on restoration of the temperature. We speculate that the switch regulates UBQLN2 function in the heat shock response because elevation of the temperature from 37 °C to 42 °C dramatically increased in vitro binding between UBQLN2 and HSPA1B. Furthermore, restoration of the temperature to 37 °C decreased HSPA1B binding. By comparison to wild type (WT) UBQLN2, we found that all five ALS/FTD mutant UBQLN2 proteins we examined had attenuated alterations in tryptophan fluorescence when shifted to 42 °C, suggesting that the conformational switch is crippled in the mutants. Paradoxically, all five mutants bound similar amounts of HSPA1B compared to WT UBQLN2 protein at 42 °C, suggesting that either the conformational switch is not instrumental for HSPA1B binding, or that, although damaged, it is still functional. Comparison of the poly-ubiquitin chain binding revealed that WT UBQLN2 binds more avidly with K63 than with K48 chains. The avidity may explain the involvement of UBQLN2 in autophagy and cell signaling. Consistent with its function in autophagy, we found UBQLN2 binds directly with LC3, the autophagosomal-specific membrane-tethered protein. Finally, we provide evidence that WT UBQLN2 can homodimerize, and heterodimerize with WT UBQLN1. We show that ALS mutant P497S-UBQLN2 protein can oligomerize with either WT UBQLN1 or 2, providing a possible mechanism for how mutant UBQLN2 proteins could bind and inactivate UBQLN proteins, causing loss of function.     

L-Serine Production by Temperature-sensitive Mutants of Methanol-utilizing Bacterium Pseudomonas MS 31

Temperature-sensitive mutants producing L-serine efficiently from glycine were obtained from the facultative methylotroph Pseudomonas MS 31. Forty-five mutant strains showed adequate growth on methanol at 30°C but little or no growth at 37°C. Fourteen of these mutants produced L- serine more efficiently than the wild-type strain. The typical mutant strain ts 162 showed a high conversion rate in glycine-to-L-serine when the cultivation temperature was changed from a permissive (30°C) to non-permissive state (38?42°C) together with the addition of glycine and methanol after adequate growth. The mutant strain accumulated 6.8 mg L-serine from 12 mg glycine per ml culture under optimum conditions. The reduction of L-serine degrading activity in the mutant strain seemed to contribute to the high productivity of L-serine.     

FACS-optimized mutants of the green fluorescent protein (GFP)

We have constructed a library in Escherichia coli of mutant gfp genes (encoding green fluorescent protein, GFP) expressed from a tightly regulated inducible promoter. We introduced random amino acid (aa) substitutions in the twenty aa flanking the chromophore Ser-Tyr-Gly sequence at aa 65–67. We then used fluorescence-activated cell sorting (FACS) to select variants of GFP that fluoresce between 20-and 35-fold more intensely than wild type (wt), when excited at 488 nm. Sequence analysis reveals three classes of aa substitutions in GFP. All three classes of mutant proteins have highly shifted excitation maxima. In addition, when produced in E. coli, the folding of the mutant proteins is more efficient than folding of wt GFP. These two properties contribute to a greatly increased (100-fold) fluorescence intensity, making the mutants useful for a number of applications.     

Trehalose accumulation from cassava starch and release by a highly thermosensitive and permeable mutant of <Emphasis Type="Italic">Saccharomycopsis fibuligera</Emphasis>

Highly thermosensitive and permeable mutants are the mutants from which intracellular contents can be released when they are incubated both in low osmolarity water and at non-permissive temperature (usually 37°C). After mutagenesis by using nitrosoguanidine, a highly thermosensitive and permeable mutant named A11-b was obtained from Saccharomycopsis fibuligera A11-12, a trehalose overproducer in which the acid protease gene has been disrupted. Of the total trehalose, 73.8% was released from the mutant cells suspended in distilled water after they had been treated at 37°C overnight. However, only 10.0% of the total trehalose was released from the cells of S. fibuligera A11-12 treated under the same conditions. The cell volume of the mutant cells suspended in distilled water and treated at 37°C overnight was much bigger than that of S. fibuligera A11-12 treated under the same conditions. The cell growth and trehalose accumulation of the mutant were almost the same as those of S. fibuligera A11-12 during the cultivation at the flask level and in a 5-l fermentor. Both could accumulate around 28.0% (w/w) trehalose from cassava starch. After purification, the trehalose crystal from the aqueous extract of the mutant was obtained.     

Stabilizing the heterologously expressed uric acid-xanthine transporter UapA from the lower eukaryote Aspergillus nidulans

Abstract

Despite detailed genetic and mutagenic analysis and a recent high-resolution structure of a bacterial member of the nucleobase-ascorbate transporter (NAT) family, understanding of the mechanism of action of eukaryotic NATs is limited. Preliminary studies successfully expressed and purified wild-type UapA to high homogeneity; however, the protein was extremely unstable, degrading almost completely after 48 h at 4°C. In an attempt to increase UapA stability we generated a number of single point mutants (E356D, E356Q, N409A, N409D, Q408E and G411V) previously shown to have reduced or no transport activity, but correct targeting to the membrane. The mutant UapA constructs expressed well as GFP fusions in Saccharomyces cerevisiae and exhibited similar fluorescent size exclusion chromatography (FSEC) profiles to the wild-type protein, following solubilization in 1% DDM, LDAO or OM + 1 mM xanthine. In order to assess the relative stabilities of the mutants, solubilized fractions prepared in 1% DDM + 1 mM xanthine were heated at 45°C for 10 min prior to FSEC. The Q408E and G411V mutants gave markedly better profiles than either wild-type or the other mutants. Further FSEC analysis following solubilization of the mutants in 1% NG ± xanthine confirmed that G411V is more stable than the other mutants, but showed that Q408E is unstable under these conditions. G411V and an N-terminally truncated construct G411VΔ1-11 were submitted to large-scale expression and purification. Long-term stability analysis revealed that G411VΔ1-11 was the most stable construct and the most suited to downstream structural studies.     

Use of green fluorescent protein as A non-destructive marker for peanut genetic transformation

Summary The ability to non-destructively visualize transient and stable gene expression has made green fluorescent protein (GFP) a most efficient reporter gene for routine plant transformation studies. We have assessed two fluorescent protein mutants, enhanced GFP (EGFP) and enhanced yellow fluorescent protein (EYFP), under the control of the CaMV35S promoter, for their transient expression efficiencies after particle bombardment of embryogenic cultures of the peanut cultivar, Georgia Green. A third construct (p524EGFP.1) that expressed EGFP from a double 35S promoter with an AMV enhancer sequence also was compared. The brightest and most dense fluorescent signals observed during transient expression were from p524EGFP. 1 and EYFP. Optimized bombardment conditions consisted of 0.6 μm diameter gold particles, 12410 kPa bombardment pressure, 95 kPa vacuum pressure, and pretreatment with 0.4 M mannitol. Bombardments with p524EGFP.1 produced tissue sectors expressing GFP that could be visually selected under the fluorescence microscope over multiple subcultures. Embryogenic lines selected for GFP expression initially may have been chimeric since quantitative analysis of expression sometimes showed an increase when GFP-expressing lines, that also contained a hygromycin-resistance gene, subsequently were cultured on hygromycin. Transformed peanut plants expressing GFP were obtained from lines selected either visually or on hygromycin. Integration of the gfp gene in the genomic DNA of regenerated plants was confirmed by Southern blot hybridization and transmission to progeny.