Michele Bellucci

Zeolin. A New Recombinant Storage Protein Constructed Using Maize γ-Zein and Bean Phaseolin

The major seed storage proteins of maize (Zea mays) and bean (Phaseolus vulgaris), zein and phaseolin, accumulate in the endoplasmic reticulum (ER) and in storage vacuoles, respectively. We show here that a chimeric protein composed of phaseolin and 89 amino acids of γ-zein, including the repeated and the Pro-rich domains, maintains the main characteristics of wild-type γ-zein: It is insoluble unless its disulfide bonds are reduced and forms ER-located protein bodies. Unlike wild-type phaseolin, the protein, which we called zeolin, accumulates to very high amounts in leaves of transgenic tobacco (Nicotiana tabacum). A relevant proportion of the ER chaperone BiP is associated with zeolin protein bodies in an ATP-sensitive fashion. Pulse-chase labeling confirms the high affinity of BiP to insoluble zeolin but indicates that, unlike structurally defective proteins that also extensively interact with BiP, zeolin is highly stable. We conclude that the γ-zein portion is sufficient to induce the formation of protein bodies also when fused to another protein. Because the storage proteins of cereals and legumes nutritionally complement each other, zeolin can be used as a starting point to produce nutritionally balanced and highly stable chimeric storage proteins.

The human immunodeficiency virus antigen Nef forms protein bodies in leaves of transgenic tobacco when fused to zeolin

Protein bodies (PB) are stable polymers naturally formed by certain seed storage proteins within the endoplasmic reticulum (ER). The human immunodeficiency virus negative factor (Nef) protein, a potential antigen for the development of an anti-viral vaccine, is highly unstable when introduced into the plant secretory pathway, probably because of folding defects in the ER environment. The aim of this study was to promote the formation of Nef-containing PB in tobacco (Nicotiana tabacum) leaves by fusing the Nef sequence to the N-terminal domains of the maize storage protein γ-zein or to the chimeric protein zeolin (which efficiently forms PB and is composed of the vacuolar storage protein phaseolin fused to the N-terminal domains of γ-zein). Protein blots and pulse–chase indicate that fusions between Nef and the same γ-zein domains present in zeolin are degraded by ER quality control. Consistently, a mutated zeolin, in which wild-type phaseolin was substituted with a defective version known to be degraded by ER quality control, is unstable in plant cells. Fusion of Nef to the entire zeolin sequence instead allows the formation of PB detectable by electron microscopy and subcellular fractionation, leading to zeolin–Nef accumulation higher than 1% of total soluble protein, consistently reproduced in independent transgenic plants. It is concluded that zeolin, but not its γ-zein portion, has a positive dominant effect over ER quality control degradation. These results provide insights into the requirements for PB formation and avoidance of quality-control degradation, and indicate a strategy for enhancing foreign protein accumulation in plants.

Genetic transformation of the sugar beet plastome

It is very important for the application of chloroplast engineering to extend the range of species in which this technology can be achieved. Here, we describe the development of a chloroplast transformation system for the sugar beet (Beta vulgaris L. ssp. vulgaris, Sugar Beet Group) by biolistic bombardment of leaf petioles. Homoplasmic plastid-transformed plants of breeding line Z025 were obtained. Transformation was achieved using a vector that targets genes to the rrn16/rps12 intergenic region of the sugar beet plastome, employing the aadA gene as a selectable marker against spectinomycin and the gfp gene for visual screening of plastid transformants. gfp gene transcription and protein expression were shown in transplastomic plants. Detection of GFP in Comassie blue-stained gels suggested high GFP levels. Microscopy revealed GFP fluorescence within the chloroplasts. Our results demonstrate the feasibility of engineering the sugar beet chloroplast genome; this technology provides new opportunities for the genetic improvement of this crop and for social acceptance of genetically modified sugar beet plants.

Protein Domains Involved in Assembly in the Endoplasmic Reticulum Promote Vacuolar Delivery when Fused to Secretory GFP, Indicating a Protein Quality Control Pathway for Degradation in the Plant Vacuole

The correct folding and assembly of newly synthesized secretory proteins are monitored by the protein quality control system of the endoplasmic reticulum (ER). Through interactions with chaperones such as the binding protein (BiP) and other folding helpers, quality control favors productive folding and sorts for degradation defective proteins. A major route for quality control degradation identified in yeast, plants, and animals is constituted by retrotranslocation from the ER to the cytosol and subsequent disposal by the ubiquitin/proteasome system, but alternative routes involving the vacuole have been identified in yeast. In this study, we have studied the destiny of sGFP418, a fusion between a secretory form of GFP and a domain of the vacuolar protein phaseolin that is involved in the correct assembly of phaseolin and in BiP recognition of unassembled subunits. We show that sGFP418, despite lacking the phaseolin vacuolar sorting signal, is delivered to the vacuole and fragmented, in a process that is inhibited by the secretory traffic inhibitor brefeldin A. Moreover, a fusion between GFP and a domain of the maize storage protein gamma-zein involved in zein polymerization also undergoes post-translational fragmentation similar to that of sGFP418. These results show that defective secretory proteins with permanently exposed sequences normally involved in oligomerization can be delivered to the vacuole by secretory traffic. This strongly suggests the existence of a plant vacuolar sorting mechanism devoted to the disposal of defective secretory proteins.

Plastid Proteostasis and Heterologous Protein Accumulation in Transplastomic Plants

In spite of a huge number of reports on successful foreign protein production in plastid, in many cases the expression level of other recombinant proteins in the transplastomic plants appears to be very low or even undetectable. We believe that this is mainly due to our limited knowledge of the mechanisms in plastids influencing the maintenance of protein homeostasis, or proteostasis. Plastids retain a whole series of mechanisms for the preservation of their protein balance, including specific proteases, transcriptional and translational control, as well as molecular chaperones and enzymes useful in protein folding. Therefore, it is important to develop basic studies in factors regulating protein synthesis, stability, folding, targeting, and accumulation in plastids, including the protein quality control which contributes to the functional integrity of proteins. Our intention here is not to provide a comprehensive review of the mechanisms that regulate plastid proteostasis, but to discuss some recent insights into this field which might bring beneficial applications in plastid biotechnology for transgene expression and foreign protein accumulation.

Zein accumulation in forage species (Lotus corniculatus and Medicago sativa) and co-expression of the γ-zein:KDEL and β-zein: KDEL polypeptides in tobacco leaf

Abstract. Plants of birdsfoot trefoil (Lotus corniculatus), alfalfa (Medicago sativa) and tobacco (Nicotianatabacum) were transformed by Agrobacterium with binary vectors harbouring genes that code either for wild-type and γ-zein:KDEL, or for β-zein:KDEL. The maize seed storage proteins γ-zein and β-zein are rich in sulphur amino acids, and our long-term goal is to improve alfalfa and birdsfoot trefoil forage quality. Significant levels of zeins were detected in leaves of birdsfoot trefoil transformants, ranging up to 0.055% and 0.30% of total extractable protein for γ-zein and β-zein:KDEL, respectively. In leaves of alfalfa, the γ-zein:KDEL expression level was up to 0.026% of the total extractable protein. From a F1 population of transgenic tobacco, a plant was selected in which the amount of zeins (γ-zein:KDEL plus β-zein:KDEL) accounted for 1.1% of the total extractable protein.

Traffic of Human α-Mannosidase in Plant Cells Suggests the Presence of a New Endoplasmic Reticulum-to-Vacuole Pathway without Involving the Golgi Complex

Noncanonical protein traffic from the endoplasmic reticulum to the vacuole may bypass the Golgi complex altogether. The transport of secretory proteins from the endoplasmic reticulum to the vacuole requires sorting signals as well as specific transport mechanisms. This work is focused on the transport in transgenic tobacco (Nicotiana tabacum) plants of a human α-mannosidase, MAN2B1, which is a lysosomal enzyme involved in the turnover of N-linked glycoproteins and can be used in enzyme replacement therapy. Although ubiquitously expressed, α-mannosidases are targeted to lysosomes or vacuoles through different mechanisms according to the organisms in which these proteins are produced. In tobacco cells, MAN2B1 reaches the vacuole even in the absence of mannose-6-phosphate receptors, which are responsible for its transport in animal cells. We report that MAN2B1 is targeted to the vacuole without passing through the Golgi complex. In addition, a vacuolar targeting signal that is recognized in plant cells is located in the MAN2B1 amino-terminal region. Indeed, when this amino-terminal domain is removed, the protein is retained in the endoplasmic reticulum. Moreover, when this domain is added to a plant-secreted protein, the resulting fusion protein is partially redirected to the vacuole. These results strongly suggest the existence in plants of a new type of vacuolar traffic that can be used by leaf cells to transport vacuolar proteins.

Inhibition of Proteolytic Enzymes from Pseudomonas fluorescens ATCC 948 and Angiotensin I-Converting Enzyme by Peptides from Zein, Hordein, and Gluten Hydrolysates

Peptides inhibitory to partially purified endopeptidase and crude proteinase from Pseudomonas fluorescens ATCC 948 were isolated from tryptic hydrolysates of zein and hordein by reversed-phase fast protein liquid chromatography and identified by sequencing. The sequences are Ser-Ala-Tyr-Pro-Gly-Gln-Ile-Thr-Ser-Asn and Gln-Val-Ser-Leu-Asn-Ser-Gly-Tyr-Tyr for peptides from zein and hordein, respectively. Inhibitions of >85% and from >50 to >85% were determined on endopeptidase and proteinase by peptides from zein and hordein. Ki values ranged from 4 to 32 μM. The same peptides also showed inhibition of the angiotensin I-converting enzyme. The concentrations of peptides providing 50% inhibition of angiotensin I-converting enzyme were 7 and 23 μM for the decapeptide and nonapeptide, respectively. Other fractions containing peptides with less inhibitory activity were detected in the zein as well as in the gluten tryptic digests.

Unconventional pathways of secretory plant proteins from the endoplasmic reticulum to the vacuole bypassing the Golgi complex

Studies on the basic mechanisms that regulate vacuolar delivering of proteins synthesized in the endoplasmic reticulum (ER) have a great importance in plant cell biology. Indeed, many aspects of plant physiology are affected by this intracellular traffic, for example, germination or reaction to biotic stresses due to the accumulation of storage proteins in seeds or enzymes in vegetative tissues, respectively. Up to now, the Golgi complex has been considered the main hub in the sorting of vacuolar secretory proteins; those polypeptides able to reach their final destination without the aid of this organelle are regarded as exceptions to an established route. This mini-review aims to emphasize the existence of several Golgi-independent pathways involved in the trafficking of different types of vacuolar proteins.

An engineered C-terminal disulfide bond can partially replace the phaseolin vacuolar sorting signal.

Seed storage proteins accumulate either in the endoplasmic reticulum (ER) or in vacuoles, and it would appear that polymerization events play a fundamental role in regulating the choice between the two destinies of these proteins. We previously showed that a fusion between the Phaseolus vulgaris vacuolar storage protein phaseolin and the N-terminal half of the Zea mays prolamin gamma-zein forms interchain disulfide bonds that facilitate the formation of ER-located protein bodies. Wild-type phaseolin does not contain cysteine residues, and assembles into soluble trimers that transiently polymerize before sorting to the vacuole. These transient interactions are abolished when the C-terminal vacuolar sorting signal AFVY is deleted, indicating that they play a role in vacuolar sorting. We reasoned that if the phaseolin interactions directly involve the C terminus of the polypeptide, a cysteine residue introduced into this region could stabilize these transient interactions. Biochemical studies of two mutated phaseolin proteins in which a single cysteine residue was inserted at the C terminus, in the presence (PHSL*) or absence (Delta 418*) of the vacuolar signal AFVY, revealed that these mutated proteins form disulphide bonds. PHSL* had reduced protein solubility and a vacuolar trafficking delay with respect to wild-type protein. Moreover, Delta 418* was in part redirected to the vacuole. Our experiments strongly support the idea that vacuolar delivery of phaseolin is promoted very early in the sorting process, when polypeptides are still contained within the ER, by homotypic interactions.