Prospects for manipulating the vegetative-reproductive balance in horticultural crops through nitrogen nutrition: a review

1996 ◽  
Vol 47 (1) ◽  
pp. 47 ◽  
Author(s):  
DO Huett
Keyword(s):  
Vegetative Growth ◽  
N Uptake ◽  
Fruit Growth ◽  
Growth And Yield ◽  
Sand Culture ◽  
Vegetable Crops ◽  
Fruit Crops ◽  
Horticultural Crops ◽  
N Rates ◽  
Subtropical Fruit

This review examines the prospects for manipulating the vegetative-reproductive balance in horticultural crops through nitrogen (N) nutrition. It also examines whether incorrect timing or excessive applications of N stimulate vegetative growth at the expense of reproductive growth. Productivity of horticultural crops is dependent on an adequate N status because photosynthetic capacity is dependent on leaf N content per unit area. Efficient N uptake occurs during periods of active growth and depends on active photosynthesis. Most N in exposed leaves is accumulated as protein and the uptake and conversion to protein requires a carbohydrate (CHO) supply. A feedback mechanism has been proposed from shoots to roots in the control of N uptake, because ammonium and nitrate uptake do not increase at supraoptimal concentrations. Stored CHO and nutrients support actively growing shoots and inflorescences and while vegetative and reproductive meristems compete as sinks, fruit growth depends principally on current photosynthesis. Most of the season's N uptake by deciduous trees occurs during the post-fruit maturity period in late summer and autumn in vegetative growth which is remobilized prior to leaf fall in late autumn into storage. The N is redistributed the following spring to support new season leaf and fruit growth. In sand culture studies conducted with 2-year-old peach and apple trees, an N deficiency which led to inadequate tree N reserves in winter inhibited flowering, fruit set and vegetative growth the following spring. N applied during spring is poorly assimilated. For Prunus spp., 90% of the N contained in the spring vegetative flush is derived from storage, indicating that exogenous N applications at that time are unlikely to influence that season's growth. Vegetable crops which have high growth and N uptake rates compared with tree fruit crops (maximum N uptake rate for tomato 66 kg/ha.week v. peach 1.3 kg/ha.week) rely on exogenous N and current photosynthesis to support growth. In studies where very high N rates were applied to horticultural crops, tree crops were unaffected except in citrus where yield was depressed and tree size was unaffected. The growth and yield of most vegetable crops were depressed at high N rates while at these high N rates, tomato yields were increased while vegetative growth was unaffected. Where a depression in tomato growth occurred at high N rates, it was caused by a salt effect, although chloride at the same osmotic potential depresses growth much more than nitrate. In subtropical fruit and nut crops such as lychee, macadamia and avocado, timing and rate of N were not detrimental to yield. Soil N, tree N and CHO reserves buffer against an external N supply and hence the ability of applied N to manipulate the vegetative-reproductive balance. More work is required to establish the extent and subsequent effect of competition between the vegetative flushes and inflorescence growth for subtropical fruit crops in particular.

Timing of 15N fertiliser application, partitioning to reproductive and vegetative tissue, and nutrient removal by field-grown low-chill peaches in the subtropics

1999 ◽  
Vol 50 (2) ◽  
pp. 211 ◽  
Author(s):  
D. O. Huett ◽  
G. R. Stewart
Keyword(s):  
Nutrient Removal ◽  
Vegetative Growth ◽  
N Uptake ◽  
Fruit Yield ◽  
Growth And Yield ◽  
Winter Period ◽  
N Recovery ◽  
N Application ◽  
Vegetative Tissues ◽  
Reproductive Tissues

The effect of timing of nitrogen (N) application as 15N-enriched ammonium sulfate (50 kg N/ha) on the growth response and N uptake by vegetative and reproductive tissues was investigated in the low-chill peach cv. Flordagem growing on a krasnozem soil at Alstonville. Nitrogen was applied in late August, late September, late October, mid February, and early May. Tree parts were sampled for 15N at 4 and 8 weeks after application and after fruit harvest in December the following season. After fruit yield was measured, trees were excavated and divided into parts for dry weight and nutrient concentration determinations, and fertiliser N recovery and to estimate tree nutrient removal. Nitrogen enrichment was detected in all plant parts within 4 weeks of N application, irrespective of timing, and was greatest in rapidly growing tissues such as laterals, leaves, and fruit. The most rapid (P < 0.05) 15N enrichment in vegetative tissues resulted from September, October, and February N applications and for fruit from a September application. The level of enrichment 4 weeks after fertiliser N application was similar for vegetative and reproductive tissues. The timing of N application in the first season had no effect on fruit yield and vegetative growth the following season. At tree removal, the recovery of fertiliser N in most tree parts increased (P < 0.05) as fertiliser N application was delayed from October to May the previous season. Maximum contribution of absorbed N to whole tree N was 10–11% for laterals, leaf, and fruit. Data from this study indicate that vegetative and reproductive growth have similar demand for absorbed N, and that uptake of fertiliser N is most rapid when an application precedes a period of rapid growth. Over 2 seasons, recovery of applied fertiliser N was 14.9–18.0% in the tree, confirming that stored N and the soil N pool are the dominant sources of tree N. The recovery of fertiliser N from the May application was 18% even though uptake in all tree parts including roots at 4 weeks after application was very low, indicating that tree fertiliser N uptake occurred when growth resumed after the dormant winter period. The low proportion and recovery of fertiliser N in the tree confirm the lack of immediate influence of applied N to vegetative growth and yield. Annual crop nutrient removal is a sound basis for fertiliser recommendations, and for the Flordagem orchard (1000 trees/ha), it consisted of fruit plus 70% of laterals (removed at pruning) plus 20% of leaf. Removal in vegetative tissues was relatively low at (kg/ha) 14 N, 1 P, 12 K, 13 Ca, and 2 Mg. The addition of fruit at a yield of 25 t/ha increased total nutrient removal to (kg/ha) 46 N, 5 P, 54 K, 14 Ca, and 5 Mg.

scholarly journals Foliar Application of Protein Hydrolysates on Baby-Leaf Spinach Grown at Different N Levels

Agronomy ◽  
2021 ◽  
Vol 12 (1) ◽  
pp. 36
Author(s):  
Anna Bonasia ◽  
Giulia Conversa ◽  
Corrado Lazzizera ◽  
Antonio Elia
Keyword(s):  
Photosynthetic Activity ◽  
Foliar Application ◽  
N Uptake ◽  
Protein Hydrolysates ◽  
Growth And Yield ◽  
N Availability ◽  
Nitrate Accumulation ◽  
N Assimilation ◽  
N Rates ◽  
N Use

Surpluses of N are associated with environmental and health problems. To optimise N use and reduce nitrate accumulation in leafy species like spinach, the application of biostimulants is suggested. An experiment in controlled conditions (growth chamber/soilless) evaluated baby-spinach responses to two protein hydrolysates (PHs) from plant (legume, Trainer®) and animal (meat, Isabion®) sources, combined with three N rates: 2 (N2, deficient), 8 (N8, sub-optimal), and 14 (N14, optimal) mM of N. Biometrical and morphological traits of shoots and roots as well as the physio-metabolic (gas exchange, N assimilation, and NUtE), physical, mineral, and antioxidant profiles of leaves were assessed. The legume-PH boosts growth and yield only at the highest N conditions, while there was no effect at lower N rates. The legume-PH modulates root architecture and chlorophylls has positive responses only at optimal N availability, such as an increase in N uptake, leaf expansion, and photosynthetic activity at the canopy level. The PHs do not improve NUtE, leaf colour, consistency, cations, or antioxidants. Neither do PHs have any effect on reducing nitrate accumulation. Legume-PH improves N assimilation only at optimal N availability, while meat-PH does not, reaching the highest nitrate value at the highest N rate (2677 mg kg−1 fw), even if this value is under the EC limits for fresh spinach.

Effect of Brassica break crops on the growth and yield of wheat

1994 ◽  
Vol 45 (3) ◽  
pp. 529 ◽  
Author(s):  
JA Kirkegaard ◽  
PA Gardner ◽  
JF Angus ◽  
E Koetz
Keyword(s):  
Methyl Bromide ◽  
Vegetative Growth ◽  
Field Experiments ◽  
N Uptake ◽  
Indian Mustard ◽  
Gaeumannomyces Graminis ◽  
Growth And Yield ◽  
Average Increase ◽  
Mineral N ◽  
Brassica Crops

The effect of the Brassica crops, canola and Indian mustard, on the growth and yield of subsequent wheat crops was investigated in field experiments at four sites in southern New South Wales. In all experiments, shoot growth, root growth, disease incidence and water and nitrogen use of wheat following the Brassica crops were compared with wheat following wheat. Linseed and field peas were included as break crops at some sites for comparison. At one site, methyl bromide fumigation was used to investigate break crop effects in the absence of soil-borne pathogens. Growth improvements following break crops were evident at an early stage (4 leaf stage), but were not related to levels of soil mineral N or the incidence of plants affected by Gaeumannomyces graminis var. tritici (take-all) or Rhizoctonia solani. At two of the four sites, early vegetative growth was greater following Indian mustard than following canola. Treatment with methyl bromide led to increased vegetative growth of wheat following all crops, but the ranking of the break crop effect was maintained, with wheat growth after Indian mustard>canola>wheat. The average increase in shoot biomass at anthesis following the break crops was 29%, varying from 12 to 46% according to site and break crop species. The effect of break crops on grain yield was influenced by water availability after anthesis. At one site, where 89 mm of rain fell after anthesis, the early improvements in growth persisted until maturity, and yield was significantly improved following the break crops. At the other three sites, less than 20 mm of rain fell after anthesis, and the greater biomass of wheat following break crops resulted in rapid depletion of soil water. The increased water deficit during grain filling reduced grain size, and no yield benefit was observed. As a result of increased pre-anthesis growth, wheat following break crops accumulated more N at anthesis in above-ground biomass at all sites. This N was redistributed into the grain after anthesis resulting in an average increase of 1.5% in grain protein in wheat following break crops. At one site, the increased N uptake in the crop was associated with less mineral N remaining in the profile at harvest. The results indicate the potential for break crops to improve the yield and protein levels of subsequent wheat crops, although the magnitude of these effects is dependent on seasonal conditions. The nature of the early growth improvements remains uncertain. However, the results from two of the sites support a previous report of the superior break-crop effect of Indian mustard.

scholarly journals Horticultural Crops Grown at Home Gardens in Rural Areas of South Sumatra, Indonesia

HortScience ◽  
1995 ◽  
Vol 30 (4) ◽  
pp. 891C-891
Author(s):  
Benyamin Lakitan
Keyword(s):  
Sea Level ◽  
Rural Areas ◽  
Similarity Index ◽  
Average Density ◽  
Home Gardens ◽  
Vegetable Crops ◽  
Fruit Crops ◽  
Horticultural Crops ◽  
Tidal Swamp ◽  
At Home

A survey has been conducted to evaluate kinds of horticultural crops grown at home gardens at 40 villages in South Sumatra Province. The villages were purposely selected to represent all geomorphological regions of the province, from highland (>1400 m above sea level) to tidal swamp along the coastal. Ten home gardens were randomly selected at each village. Most common horticultural crops found at home gardens were fruits crops such as banana, pineapple, and soursop. Surprisingly, vegetable crops were rarely (<22.0%) found at home gardens. Based on Sorenson's similarity index, it can be concluded that kinds of fruit crops grown were similar at most villages surveys, except for those at altitudes higher than 1000 m above sea level. Average density of perennial fruit tress was 4.6 trees/100 m2, with a range from 1.7 to 10.9 trees/100 m2.

Effects of duration of coverage with spunbonded polyester rowcovers on growth and yield of bell pepper (Capsicum annuum L.)

2003 ◽  
Vol 83 (2) ◽  
pp. 387-391 ◽  
Author(s):  
D. Waterer
Keyword(s):  
Capsicum Annuum ◽  
High Temperatures ◽  
Vegetative Growth ◽  
Insect Pests ◽  
Warm Season ◽  
Growing Season ◽  
Growth And Yield ◽  
Vegetable Crops ◽  
Cropping Seasons ◽  
Yield Responses

Transparent rowcovers installed at transplanting and removed as growing conditions improve are commonly employed to promote development of warm-season vegetable crops. In regions with a brief and cool growing season, short-stature warm-season crops such as peppers could potentially benefit from being kept under the rowcovers for extended periods after transplanting. This study examined the influence of duration of coverage with spunbonded polyester rowcovers on vegetative growth, fruit yields and degree of fruit maturity of bell peppers over the 1999, 2000 and 2001 cropping seasons in Saskatchewan, Canada. Eight-week-old transplants of several cultivars of pepper were covered for 6 wk or 10 wk after transplanting or for the duration of the growing season. All growth and yield responses to the duration of coverage were consistent across the cultivars tested. In 1999, extending the period of coverage reduced aboveground vegetative growth of the crop, otherwise vegetative growth was not influenced by the duration of coverage. During the relatively cool 2000 cropping season, the duration of coverage had no effect on fruit yields or the proportion of the fruit that matured to red prior to frost. By contrast, in the warmer 1999 and 2001 cropping seasons, fruit yields declined as the duration of coverage increased. Excessively high temperatures interfere with fruit set in peppers. These results suggest that the risk of exposing the crop to excessively high temperatures may be increased by extending the period of coverage into the warmer periods of the growing season. Extending the period of coverage beyond the standard 6 wk also required additional labor and occasionally exacerbated problems with weeds and insect pests. Key words: Rowcovers, microclimate, ripening, pepper, Capsicum annuum

Rootstocks.

2021 ◽  
Author(s):  
Ed Durner ◽  
Ed Rutgers Durner
Keyword(s):  
Root System ◽  
Lower Portion ◽  
Vegetable Crops ◽  
Single Plant ◽  
Fruit Crops ◽  
Horticultural Crops ◽  
Stem Piece ◽  
Vegetative Bud ◽  
Insight Into

Abstract Plants of many horticultural crops consist of multiple genetic systems, two or more distinct genotypes joined together as a single plant. The components are identified as the rootstock, interstem and scion. Grafting and budding are the processes that combine these components to establish vascular continuity between them to produce a single plant. Grafting may be natural or human initiated, forced grafting. This datasheet will mainly consider forced grafting with only a brief discussion of natural grafting. The rootstock is that component of the plant that fuses with the scion and provides the plants root system. Other terms used to describe this lower portion of the plant include stock and understock. Stock is synonymous with both rootstock and understock. Understock implies that the lower portion of the plant provides both the root system and some of the trunk while rootstock or stock implies that only the root system is provided by the lower piece. When grafting is performed high on the rootstock, the rootstock may also provide scaffold limbs. The scion is the plants shoot system. It is the component that produces the desired commodity in most cases, which are usually flowers or fruit. In perennials, the scion is nearly always vegetatively propagated. In grafted vegetables, the scion is usually propagated via seed. An interstem is a third genetic component of some grafted plants and is often selected to provide compatibility between the rootstock and the scion. Both grafting and budding combine dissimilar genotypes into one plant. Budding is a form of grafting where a single vegetative bud is used as the scion or interstem. Grafting refers to the condition where more than one bud on a common stem piece are combined with the rootstock or interstem. Perennial ornamental and fruit crops are the grafted crops that are familiar to most horticulturists. Annual vegetable crops are increasingly being grown as grafted plants and interest in using them in commercial production is rising steeply. Short lists of common rootstocks for a number of ornamental, fruit, nut and vegetable crops are presented in Tables 1-3 (at the bottom of this article). These lists are by no means complete, but provide an insight into the large number of rootstocks available in modern horticultural production. Specific recommendations for an area should be obtained from local experts. Good rootstocks should possess as many of the following crop appropriate characteristics as possible: affordable, long term graft compatible, easily propagated, promotes precocity and productivity, controls scion vigour, conveys pest resistance, improves stress tolerance, and has minimal suckering.

scholarly journals Effectiveness of Fall versus Spring Soil Fertilization of Field-grown Peach Trees

2001 ◽  
Vol 126 (5) ◽  
pp. 644-648 ◽  
Author(s):  
F.J.A. Niederholzer ◽  
T.M. DeJong ◽  
J.-L. Saenz ◽  
T.T. Muraoka ◽  
S.A. Weinbaum
Keyword(s):  
Vegetative Growth ◽  
Prunus Persica ◽  
N Uptake ◽  
Fruit Size ◽  
Growth And Yield ◽  
Soil N ◽  
N Accumulation ◽  
Total N ◽  
Peach Trees ◽  
Leaf N

Marginally nitrogen (N)-deficient, field-grown peach trees [Prunus persica (L.) Batsch (Peach Group) 'O' Henry'] were used to evaluate seasonal patterns of tree N uptake, vegetative growth, and yield following fall or spring fertilization. Sequential tree excavations and determinations of tree biomass and N contents in Feb. and Aug. allowed estimation of N uptake by fall-fertilized trees between September 1993 and mid-February 1994. Total N uptake (by difference) by spring- fertilized trees as well as additional N uptake by fall-fertilized trees over the spring.summer period was also determined. In fall-fertilized trees, only 24% of tree N accumulation between September 1993 and August 1994 occurred during the fall/dormancy period. Spring- and fall-fertilized trees exhibited comparable vegetative growth, fruit size, and yield despite lower dormant tree N contents and tissue N concentrations in the spring-fertilized trees. Fifty percent of tree leaf N content was available for resorption from leaves for storage in woody tree parts. This amount (N at ~30.kghhhhhhha-1) was calculated to represent more than 80% of the N storage capacity in perennial tree parts of fertilized peach trees. Our data suggest that leaf N resorption, even without fall soil N application, can provide sufficient N from storage to initiate normal growth until plant-available soil N is accessed in spring.

scholarly journals Effects of Nitrogen Fertilization and Soil Inoculation of Sulfur-Oxidizing or Nitrogen-Fixing Bacteria on Onion Plant Growth and Yield

2011 ◽  
Vol 2011 ◽  
pp. 1-6 ◽  
Author(s):  
Nemat M. Awad ◽  
A. A. Abd El-Kader ◽  
M. Attia ◽  
A. K. Alva
Keyword(s):  
Plant Height ◽  
N Uptake ◽  
Growth And Yield ◽  
Onion Plant ◽  
Soil Inoculation ◽  
Allium Cepa L ◽  
Reclaimed Soil ◽  
Sulfur Oxidizing ◽  
Yield Quality ◽  
N Rates

A field experiment was conducted in a newly reclaimed soil at El-Saff region, El-Giza Governorate, Egypt to study the effects of different rates of nitrogen (N: 62 to 248 kg ha-1) with or without soil inoculation of sulfur- (S-) oxidizing bacteria (SoxB) and combined inoculation of SoxB and N-fixing bacteria (NFxB) on yield, quality and nutritional status of onion (Allium cepa L., “Giza 20”). Elemental S at 620 kg ha-1was applied to all treatments. Application of N at 62, 124, and 248 kg ha-1rates increased onion yield, plant height, and N uptake by 28 to 76%, 32 to 53%, and 61 to 145%, as compared to those of the plants that received no N. Inoculation of SoxB at various N rates increased onion yields by 47 to 69% and N uptake by 76 to 93%, as compared to those of the plants which received the respective rates of N but no SoxB inoculation. Inoculation with SoxB and NFxB increased onion yield by 221%, plant height by 62%, and N uptake by 629%, as compared to those of the plants grown without inoculation and no N applied.

NLEAP Computer Model and Multiple Linear Regression Prediction of Nitrate Leaching in Vegetable Systems

2002 ◽  
Vol 12 (2) ◽  
pp. 250-256 ◽  
Author(s):  
Hudson Minshew ◽  
John Selker ◽  
Delbert Hemphill ◽  
Richard P. Dick
Keyword(s):  
Linear Regression ◽  
Multiple Linear Regression ◽  
Nitrate Leaching ◽  
Cover Crops ◽  
N Uptake ◽  
N Leaching ◽  
Residual Soil ◽  
Vegetable Crops ◽  
Crop N Uptake ◽  
Mlr Model

Predicting leaching of residual soil nitrate-nitrogen (NO3-N) in wet climates is important for reducing risks of groundwater contamination and conserving soil N. The goal of this research was to determine the potential to use easily measurable or readily available soilclimatic-plant data that could be put into simple computer models and used to predict NO3 leaching under various management systems. Two computer programs were compared for their potential to predict monthly NO3-N leaching losses in western Oregon vegetable systems with or without cover crops. The models were a statistical multiple linear regression (MLR) model and the commercially available Nitrate Leaching and Economical Analysis Package model (NLEAP 1.13). The best MLR model found using stepwise regression to predict annual leachate NO3-N had four independent variables (log transformed fall soil NO3-N, leachate volume, summer crop N uptake, and N fertilizer rate) (P < 0.001, R2 = 0.57). Comparisons were made between NLEAP and field data for mass of NO3-N leached between the months of September and May from 1992 to 1997. Predictions with NLEAP showed greater correlation to observed data during high-rainfall years compared to dry or averagerainfall years. The model was found to be sensitive to yield estimates, but vegetation management choices were limiting for vegetable crops and for systems that included a cover crop.

Sign in / Sign up

Export Citation Format

Share Document