Multi-domain GFP-like proteins from two species of marine hydrozoans

Proteins homologous to Green Fluorescent Protein (GFP) are widely used as genetically encoded fluorescent labels. Many developments of this technology were spurred by discoveries of novel types of GFP-like proteins (FPs) in nature. Here we report two proteins displaying primary structures never before encountered in natural FPs: they consist of multiple GFP-like domains repeated within the same polypeptide chain. A two-domain green FP (abeGFP) and a four-domain orange-fluorescent FP (Ember) were isolated from the siphonophore Abylopsis eschscholtzii and an unidentified juvenile jellyfish (order Anthoathecata), respectively. Only the most evolutionary ancient domain of Ember is able to synthesize an orange-emitting chromophore (emission at 571 nm), while the other three are purely green (emission at 520 nm) and putatively serve to maintain the stability and solubility of the multidomain protein. When expressed individually, two of the green Ember domains form dimers and the third one exists as a monomer. The low propensity for oligomerization of these domains would simplify their adoption as in vivo labels. Our results reveal a previously unrecognized direction in which natural FPs have diversified, suggesting new avenues to look for FPs with novel and potentially useful features.     

Function and structure of GFP-like proteins in the protein data bank

The RCSB protein databank contains 266 crystal structures of green fluorescent proteins (GFP) and GFP-like proteins. This is the first systematic analysis of all the GFP-like structures in the pdb. We have used the pdb to examine the function of fluorescent proteins (FP) in nature, aspects of excited state proton transfer (ESPT) in FPs, deformation from planarity of the chromophore and chromophore maturation. The conclusions reached in this review are that (1) The lid residues are highly conserved, particularly those on the "top" of the β-barrel. They are important to the function of GFP-like proteins, perhaps in protecting the chromophore or in β-barrel formation. (2) The primary/ancestral function of GFP-like proteins may well be to aid in light induced electron transfer. (3) The structural prerequisites for light activated proton pumps exist in many structures and it's possible that like bioluminescence, proton pumps are secondary functions of GFP-like proteins. (4) In most GFP-like proteins the protein matrix exerts a significant strain on planar chromophores forcing most GFP-like proteins to adopt non-planar chromophores. These chromophoric deviations from planarity play an important role in determining the fluorescence quantum yield. (5) The chemospatial characteristics of the chromophore cavity determine the isomerization state of the chromophore. The cavities of highlighter proteins that can undergo cis/trans isomerization have chemospatial properties that are common to both cis and trans GFP-like proteins.     

GFP-like chromoproteins as a source of far-red fluorescent proteins.

We have employed a new approach to generate novel fluorescent proteins (FPs) from red absorbing chromoproteins. An identical single amino acid substitution converted novel chromoproteins from the species Anthozoa (Heteractis crispa, Condylactis gigantea, and Goniopora tenuidens) into far-red FPs (emission lambda(max)=615-640 nm). Moreover, coupled site-directed and random mutagenesis of the chromoprotein from H. crispa resulted in a unique far-red FP (HcRed) that exhibited bright emission at 645 nm. A clear red shift in fluorescence of HcRed, compared to drFP583 (by more than 60 nm), makes it an ideal additional color for multi-color labeling. Importantly, HcRed is excitable by 600 nm dye laser, thus promoting new detection channels for multi-color flow cytometry applications. In addition, we generated a dimeric mutant with similar maturation and spectral properties to tetrameric HcRed.     

Mutant invertase proteins accumulate in the yeast endoplasmic reticulum

Summary Intercompartmental transport of secreted proteins in yeast was analysed using invertase mutants. Deletions and insertions at the BamHI (position +787) or the Asp718 (position +1159) sites of the SUC2 gene led to mutant proteins with different behaviour regarding secretion, localization and enzyme activity. The deletion mutants showed accumulation of core glycosylated material in the endoplasmic reticulum (ER) a decrease of secreted protein by 5%–30% and loss of enzyme activity. The secreted material was localized in the culture medium and not — as is normal for invertase-in the cell wall. No delay in transport from the Golgi to the cell surface was observed, indicating that the rate-limiting step for secretion is at the ER-Golgi stage. Two insertion mutants, pIPA and pIPB, retained enzyme activity. Mutant pIPB showed 10% secretion, while 60%–70% secretion was observed for pIPA. While the non-secreted material accumulated in the ER, the secreted material was present in the cell wall. The results suggest that the presence of structures incompatible with secretion leads to ER accumulation of mutated invertase.     

Induced oligomerization targets Golgi proteins for degradation in lysosomes

Manganese protects cells against forms of Shiga toxin by down-regulating the cycling Golgi protein GPP130. Down-regulation occurs when Mn binding causes GPP130 to oligomerize and traffic to lysosomes. To determine how GPP130 is redirected to lysosomes, we tested the role of GGA1 and clathrin, which mediate sorting in the canonical Golgi-to-lysosome pathway. GPP130 oligomerization was induced using either Mn or a self-interacting version of the FKBP domain. Inhibition of GGA1 or clathrin specifically blocked GPP130 redistribution, suggesting recognition of the aggregated GPP130 by the GGA1/clathrin-sorting complex. Unexpectedly, however, GPP130’s cytoplasmic domain was not required, and redistribution also occurred after removal of GPP130 sequences needed for its normal cycling. Therefore, to test whether aggregate recognition might be a general phenomenon rather than one involving a specific GPP130 determinant, we induced homo-oligomerization of two unrelated Golgi-targeted constructs using the FKBP strategy. These were targeted to the cis- and trans-Golgi, respectively, using domains from mannosidase-1 and galactosyltransferase. Significantly, upon oligomerization, each redistributed to peripheral punctae and was degraded. This occurred in the absence of detectable UPR activation. These findings suggest the unexpected presence of quality control in the Golgi that recognizes aggregated Golgi proteins and targets them for degradation in lysosomes.     

Major colour patterns of reef-building corals are due to a family of GFP-like proteins

Reef-building corals are renowned for their brilliant colours yet the biochemical basis for the pigmentation of corals is unknown. Here, we show that these colours are due to a family of GFP-like proteins that fluoresce under ultraviolet (UV) or visible light. Pigments from ten coral species were almost identical to pocilloporin (Dove et al. 1995) being dimers or trimers with approximately 28-kDa subunits. Degenerative primers made to common N-terminal sequences yielded a complete sequence from reef-building coral cDNA, which had 19.6% amino acid identity with green fluorescent protein (GFP). Molecular modelling revealed a `β-can' structure, like GFP, with 11 β-strands and a completely solvent-inaccessible fluorophore composed of the modified residues Gln-61, Tyr-62 and Gly-63. The molecular properties of pocilloporins indicate a range of functions from the conversion of high-intensity UV radiation into photosynthetically active radiation (PAR) that can be regulated by the dinoflagellate peridinin-chlorophyll-protein (PCP) complex, to the shielding of the Soret and Q_x bands of chlorophyll a and c from scattered high-intensity light. These properties of pocilloporin support its potential role in protecting the photosynthetic machinery of the symbiotic dinoflagellates of corals under high light conditions and in enhancing the availability of photosynthetic light under shade conditions. Accepted: 29 May 2000     

A purple-blue chromoprotein from Goniopora tenuidens belongs to the DsRed subfamily of GFP-like proteins

A number of recently cloned chromoproteins homologous to the green fluorescent protein show a substantial bathochromic shift in absorption spectra. Compared with red fluorescent protein from Discosoma sp. (DsRed), mutants of these so-called far-red proteins exhibit a clear red shift in emission spectra as well. Here we report that a far-red chromoprotein from Goniopora tenuidens (gtCP) contains a chromophore of the same chemical structure as DsRed. Denaturation kinetics of both DsRed and gtCP under acidic conditions indicates that the red form of the chromophore (absorption maximum at 436 nm) converts to the GFP-like form (384 nm) by a one-stage reaction. Upon neutralization, the 436-nm form of gtCP, but not the 384-nm form, renaturates instantly, implying that the former includes a chromophore in its intact state. gtCP represents a single-chain protein and, upon harsh denaturing conditions, shows three major bands in SDS/PAGE, two of which apparently result from hydrolysis of an acylimine C=N bond. Instead of having absorption maxima at 384 nm and 450 nm, which are characteristic for a GFP-like chromophore, fragmented gtCP shows a different spectrum, which presumably corresponds to a 2-keto derivative of imidazolidinone. Mass spectra of the chromophore-containing peptide from gtCP reveal an additional loss of 2 Da relative to the GFP-like chromophore. Tandem mass spectrometry of the chromopeptide shows that an additional bond is dehydrogenated in gtCP at the same position as in DsRed. Altogether, these data suggest that gtCP belongs to the same subfamily as DsRed (in the classification of GFP-like proteins based on the chromophore structure type).     

Karyophobic proteins : A category of abundant soluble proteins which accumulate in the cytoplasm

The cytoplasm of oocytes of Xenopus laevis is enriched in several soluble proteins which are either absent from the nucleus or are present there at very low concentrations. These molecules, collectively referred to as karyophobic (from the Greek verbs oβιν and oβλoθαi which are meant here in the sense of “to be afraid of” or “to avoid”) proteins represent more than 20% of the total soluble cytoplasmic proteins and include some of the most abundant soluble cellular components. They may be recovered from high-speed supernatant (S-100) fractions and, following sucrose gradient centrifugation, most of them appear in the form of complexes smaller than 8.5S. On denaturation in urea and two-dimensional gel electrophoresis these proteins appear to be comprised of polypeptides of widely different sizes (ca M_r 15 000–230 000) and isoelectric points covering a broad range of pH values (4.2–8.0). Gel filtration and isoelectric focusing of native karyophobic proteins show that the majority occur in acidic complexes smaller than M_r 150 000, including one case of a small karyophobic protein (C9; M_r 30 000). In contrast to karyophilic proteins and proteins equilibrating between nucleus and cytoplasm karyophobic soluble proteins from [³⁵S]methionine-labelled ooplasms, when injected into unlabelled oocytes, remain in the cytoplasm. Human proteins with a similar karyophobic behaviour have been identified in fractions of soluble proteins from HeLa cells; there, the major karyophobic protein (HCa, M_r 36 000) is also one of the most abundant soluble proteins.We conclude that the specific nucleocytoplasmic compartmentalization of soluble proteins is governed not only by the principles of exclusion of large molecules from nuclear uptake and the existence of karyophilic signals in certain proteins but that a series of soluble, globular proteins exist in the cytoplasm, which have other molecular features which selectively exclude them from distribution over the nucleus. The possible functional role of the selective enrichment of these abundant proteins, which so far have escaped attention, in establishing a cytoplasmic milieu is discussed.     

It's cheap to be colorful. Anthozoans show a slow turnover of GFP-like proteins

Pigments homologous to the green fluorescent protein (GFP) contribute up to approximately 14% of the soluble protein content of many anthozoans. Maintenance of such high tissue levels poses a severe energetic penalty to the animals if protein turnover is fast. To address this as yet unexplored issue, we established that the irreversible green-to-red conversion of the GFP-like pigments from the reef corals Montastrea cavernosa (mcavRFP) and Lobophyllia hemprichii (EosFP) is driven by violet-blue radiation in vivo and in situ. In the absence of photoconverting light, we subsequently tracked degradation of the red-converted forms of the two proteins in coral tissue using in vivo spectroscopy and immunochemical detection of the post-translational peptide backbone modification. The pigments displayed surprisingly slow decay rates, characterized by half-lives of approximately 20 days. The slow turnover of GFP-like proteins implies that the associated energetic costs for being colorful are comparatively low. Moreover, high in vivo stability makes GFP-like proteins suitable for functions requiring high pigment concentrations, such as photoprotection.     

GFP-like proteins as ubiquitous metazoan superfamily: evolution of functional features and structural complexity

Homologs of the green fluorescent protein (GFP), including the recently described GFP-like domains of certain extracellular matrix proteins in Bilaterian organisms, are remarkably similar at the protein structure level, yet they often perform totally unrelated functions, thereby warranting recognition as a superfamily. Here we describe diverse GFP-like proteins from previously undersampled and completely new sources, including hydromedusae and planktonic Copepoda. In hydromedusae, yellow and nonfluorescent purple proteins were found in addition to greens. Notably, the new yellow protein seems to follow exactly the same structural solution to achieving the yellow color of fluorescence as YFP, an engineered yellow-emitting mutant variant of GFP. The addition of these new sequences made it possible to resolve deep-level phylogenetic relationships within the superfamily. Fluorescence (most likely green) must have already existed in the common ancestor of Cnidaria and Bilateria, and therefore GFP-like proteins may be responsible for fluorescence and/or coloration in virtually any animal. At least 15 color diversification events can be inferred following the maximum parsimony principle in Cnidaria. Origination of red fluorescence and nonfluorescent purple-blue colors on several independent occasions provides a remarkable example of convergent evolution of complex features at the molecular level.     

Generation of efficient fingerprint for GFP-like fold and computational identification of potential GFP-like homologs

There is a considerable interest in the detection of GFP-like proteins due to their structural stability and functional usefulness. GFP-like proteins share highly conserved beta-barrel fold with 11 beta-strands. However, their low sequence identity hampers efficient identification of their homologous proteins from database. In this study, an attempt was made to generate a fingerprint for efficient detection of GFP-like proteins. Overlapped conserved residues (OCR)-based approach has been used to design a protein fingerprint based on sequentially and structurally conserved residues in secondary structures to detect homologous proteins very efficiently. Therefore, a fingerprint for GFP-like fold was designed using the OCR approach. However, its specificity was too low to be used for the identification of novel proteins. The conserved residues of loop regions were added and optimized to improve its specificity without losing its high sensitivity. The optimized fingerprint was employed to scan NR database. A total of 20 hypothetical proteins were detected, among which nine were validated as potential GFP-like homologs.     

Import of stably folded proteins into peroxisomes.

By virtue of their synthesis in the cytoplasm, proteins destined for import into peroxisomes are obliged to traverse the single membrane of this organelle. Because the targeting signal for most peroxisomal matrix proteins is a carboxy-terminal tripeptide sequence (SKL or its variants), these proteins must remain import competent until their translation is complete. We sought to determine whether stably folded proteins were substrates for peroxisomal import. Prefolded proteins stabilized with disulfide bonds and chemical cross-linkers were shown to be substrates for peroxisomal import, as were mature folded and disulfide-bonded IgG molecules containing the peroxisomal targeting signal. In addition, colloidal gold particles conjugated to proteins bearing the peroxisomal targeting signal were translocated into the peroxisomal matrix. These results support the concept that proteins may fold in the mammalian cytosol, before their import into the peroxisome, and that protein unfolding is not a prerequisite for peroxisomal import.     

Targeting of membrane proteins to endosomes and lysosomes

The pathways involved in targeting membrane proteins to lysosomes are extraordinarily complex. Newly synthesized proteins in the ER are transported to the Golgi complex, and upon arrival at the trans Golgi network (TGN) are targeted either directly to endosomes, or first to the cell surface from where they can be rapidly internalized into the endocytic pathway for delivery to lysosomes. The routes to endosomes are specified by sorting motifs in the cytoplasmic tails of the proteins that are recognized at the TGN or plasma membrane. The molecular details of these processes are just emerging.     

Lectin-like proteins accumulate as fragmentation products in bean seed protein bodies

The gene sequence of the Phaseolus vulgaris L. seed lectin-like protein (LLP) and its precursor ( 40 kDa) which is associated with the endoplasmic reticulum has been described, while the molecular characteristics of the mature protein and its cellular localization are still unknown. Our data, obtained using antibodies raised against a fusion protein, which was produced in Escherichia coli and contained most of the LLP sequence, indicate that mature LLP accumulates in the protein bodies of cotyledon cells. LLP consists of several polypeptides in the M_r range 15 000 to 20 000, which are a result of proteolytic fragmentation of the protein precursor.     

Oil body proteins sequentially accumulate throughout seed development in Brassica napus

Despite the importance of seed oil bodies (OBs) as enclosed compartments for oil storage, little is known about lipid and protein accumulation in OBs during seed formation. OBs from rapeseed (Brassica napus) consist of a triacylglycerol (TAG) core surrounded by a phospholipid monolayer embedded with integral proteins which confer high stability to OBs in the mature dry seed. In the present study, we investigated lipid and protein accumulation patterns throughout seed development (from 5 to 65 days after pollination [DAP]) both in the whole seed and in purified OBs. Deposition of the major proteins (oleosins, caleosins and steroleosins) into OBs was assessed through (i) gene expression pattern, (ii) proteomics analysis, and (iii) protein immunodetection. For the first time, a sequential deposition of integral OB proteins was established. Accumulation of oleosins and caleosins was observed starting from early stages of seed development (12-17 DAP), while steroleosins accumulated later (∼25 DAP) onwards.     

The capacity of lysosomes of cultured mammalian cells to accumulate acridine orange is destroyed by hyperthermia

Summary Lysosomes of cultured mammalian cells, derived from a transplantable murine mammary adenocarcinoma, irreversibly lose their capacity to accumulate the fluorescent dye acridine orange after hyperthermia. As acridine orange may be regarded as a fluorescent probe of the internal pH of the lysosomes, we may conclude that the ability of lysosomes to maintain a low internal pH is destroyed by hyperthermia.The effects of hyperthermia on lysosome fluorescence and on cell survival show several similarities: in both cases hyperthermia is more effective at low pH, below pH 7.0, and CCP (carbonylcyanide-m-chlorophenylhydrazone) enhances effects at low pH, but has no clear effect at pH 8.0. This leads to the conclusion that effects on lysosomes are an important and early event in cellular injury caused by hyperthermia. The activation energy, however, obtained for the effects of hyperthermia on lysosome fluorescence is about a factor of two lower than the activation energy reported for cell survival after hyperthermia. This suggests that the effect on lysosomes is not directly caused by hyperthermia but is triggered by some other hyperthermia-induced cellular damage.Abbreviations CCP carbonylcyanide-m-chlorophenylhydrazone - MES 2-(N-morpholino)ethanesulfonic acid - MOPS 2-(N-morpholino)propanesulfonic acid - Tricine N-tris(hydroxymethyl)methylglycine Supported in part by grants from the KWF (Koningin Wilhelmina Fonds) and the IRS (Interuniversitair Instituut voor Radiopathologie en Stralenbescherming)     

Ubiquitin-dependent sorting of integral membrane proteins for degradation in lysosomes

The pathways that deliver newly synthesized proteins that reside in lysosomes are well understood on comparison with our knowledge of how integral membrane proteins are sorted and delivered to the lysosome for degradation. Many membrane proteins are sorted to lysosomes following ubiquitination, which provides a sorting signal that can operate for sorting at the TGN (trans-Golgi network), at the plasma membrane or at the endosome for delivery into lumenal vesicles. Candidate multicomponent machines that can potentially move ubiquitinated integral membrane cargo proteins have been identified, but much work is still required to ascertain which of these candidates directly recognize ubiquitinated cargo and what they do with cargo after recognition. In the case of the machinery required for sorting into the lumenal vesicles of endosomes, other functions have also been determined including a link between sorting and movement of endosomes along microtubules.