Imagine a container plant that grows a lush 6 feet tall and produces delicious, soft-skinned, seedless tropical fruits. Introducing… the babaco tree.


Also known as mountain papaya, babaco is cousin to that other sweet tropical fruit of mammoth size. Commonly eaten fresh, or used in fruit salads, smoothies, and ice cream, babaco (Carica pentagona Heilborn) is believed to be a naturally occurring hybrid from Ecuador. People have been eating babaco fruit since the 1500s, but I had never heard of it until recently.

Advantages of grafting

It is pretty safe to assume that nearly all fruit and nut trees available today are grafted combinations of hardy, pest- and disease-resistant rootstock and highly productive scions. 


Grafting speeds up production because young scions can be grafted onto older rootstock. This is called precocity and it allows growers to skip the 5- to 12-year juvenile phase, when trees are focusing on root system development, rather than fruit production. Grafted trees can also selected for size. Simply graft a scion from a full-sized tree onto dwarf rootstock and you get a dwarfed tree that produces more fruit. In many cases, grafting is used to imbue a tree with pest or disease resistance. This method is also used on watermelon, tomato, eggplant, cucumber, and other vegetative plants for the same reason.


Grafting for the garden

Let me say this up front - grafting requires skill. It easy to do incorrectly. There are several factors that contribute to successful grafts, and all of them are important:

• Compatibility - Clones and members of the same species are the easiest to graft because they have identical structures [peach to peach]; two different species within the same genus can sometimes be grafted [peach to cherry]; plants in the same family, but different genera can only occasionally be grafted successfully [peach to apple]; monocots, because they lack vascular cambium, cannot be grafted.
• Alignment and surface contact - The vascular bundles of both the scion and rootstock must be in firm contact with each other, and oriented in the same direction.
• Timing - Successful grafting occurs when the scion is dormant, the rootstock is able to produce a protective callus, and temperatures are not too warm or too cold. In the Bay Area, most grafting is done January through March. 
• Site protection - Graft sites must be protected against dehydration, pests, such as vine mealybugs, and diseases until they have healed. This means using very sharp cutting tools that have been sanitized frequently throughout the process. Tapes and waxes are commonly used to seal the grafting site. Structural supports may also be needed.

Tools used in grafting

Having your tools ready ahead of time will increase your odds of successful grafting. The last thing you want is for plant tissue to dry out before you are done. [Many gardeners hold scions in their mouth as they work, to keep the plant tissue moist.] You will need sharp, sanitized pruning clippers, stretchable, biodegradable grafting tape, a sharp grafting knife, and sanitizer. You may also want to have some tree sealant or grafting wax handy.​

Chip budding is similar to T-budding, except that a chip of wood is removed from the rootstock and the bud is inserted into the space.

There are several different types of grafts:


Approach grafting joins two rooted plants together to provide more support for the developing new growth. It is also used in pleaching and can be done any time of year.
Awl grafts are hard to do well as it means poking an awl under the bark of rootstock, but not beyond the cambium layer, and inserting the scion.

Bridge grafting is used in an attempt to save a tree that has been girdled by planting identical species around the injured tree and grafting them above the injury to create a nutrient bridge over the girdled portion of trunk. A similar method, called inarch grafting, uses an existing branch of the injured tree that emerges below to injury to reconnect the supply chain of nutrients.

Four-flap grafts (or banana grafts) are a complex method of grafting, commonly used on pecans, in which bark from the rootstock is peeled back, like a banana, and applied to the scion.

In rare cases, graft hybrids, called chimera, will occur. This happens when rootstock tissues grow into the scion wood. This can lead to trees that produce flowers of both plants, plus strange combination flowers. Chimera are almost impossible to reproduce.


Whichever method you decide to use, grafting or budding, be sure to seal the area completely, either with grafting tape, tree seal, or grafting wax. This will protect against desiccation, pests, and disease, while providing some structural support, as well.


Problems associated with grafting

Grafting can provide you with added control over plants, making them more suitable to your garden theme. It can also make your foodscape healthier and more productive. But grafting requires skill and is labor intensive. Also, it is important that the proper rootstock is selected for your scions. Incompatibility may not kill the tree until several years of watering, fertilizing, and pruning have passed. Check with your local County Extension Office or rare fruit growers club for more information on compatibility before you get started.


When you first try your hand at grafting, don’t be surprised or discouraged when the alignment and pressure are insufficient, or the graft union dries out before the scion “takes” to the rootstock. This happens to beginners all the time. 


If your graft works, make sure you plant your new tree at the proper planting depth. This is critical to its health and longevity. Placing graft unions below soil level invites fungal diseases, such as crown rot.


The interaction between rootstock and scion wood can be pretty amazing when it comes to plant hormones. Check out my post on photoperiodism.


Assuming you have already collected, labeled, and kept scions cool and moist, you are now ready to begin. [If not, read my post on scions first.]


Did you know that you can graft a tomato plant onto a potato plant and get food from both?


Now you know.

You may love calico cats (I do!), or have fond memories of calico dresses from a certain prairie-crossing children’s series, but calico in the plant world is something else entirely. 

Invasive planarians

Land planarians are native to Indo-China. Sometime around 1901, soil containing these flatworms was transported to the U.S. At first, land planarians were only found in greenhouses. Now they are found in several states including: Alabama, California, Mississippi, New Jersey, New York, North Carolina, Ohio, Oklahoma, South Carolina, Tennessee, and Texas. If you find one in a state not listed, I’m sure that your local County Extension Office would love to see it. At this point, land planarians are only found in places where nursery plants go. They withstand freezing temperatures by hiding in protected areas. They cannot, however, tolerate low humidity or drought.


Land planarian description

Land planarians are flat, slimy worms. Apparently, the slime helps them move and is the only way they can maintain internal moisture levels. That slime is said to taste terrible, though I don’t know how or who figured that out. That bad taste means they have few, if any, natural predators. ​

Flatworm reproduction

Like many other flatworms, land planarians are able to reproduce either sexually or asexually. Sexual reproduction culminates in eggs being placed in cocoons that hatch in 3 weeks. A single planarian will, every couple of weeks or so, attach its tail to a rock or some other immoveable object and slime away, tearing its tail from its torso. A new tail grows from the wound, as we would expect of a flatworm. The tail segment left behind, however, does the same thing, growing a new torso and head within 10 days. [When food is scarce, it is not uncommon for land planarians to eat their own reproductive tissues.] Scientists love studying flatworms because of those reproductive habits. In one study, it was found that decapitated flatworms retained the memories of their parent worms. [I can’t make this stuff up.]



As far as invasive pests go, planarians are not a significant problem, unless you have a greenhouse or practice vermiculture. [Vermiculture refers to raising worms.] In most outdoor gardens, fluctuations in humidity help keep land planarian populations in check. If you do have a greenhouse, or raise worms, flatworms can wipe out your entire worm population in short order.



The next time you see slime trails, don't assume they were made by snails or slugs. It may be that those garden pests are on the run from something far more terrifying (to them).

Manganese toxicities

Plants can absorb too much manganese in acid soils, or under drought conditions. When acid-forming fertilizers, superphosphates (fertilizers made by treating phosphate rock with phosphoric or sulfuric acid) are used, or when nitrate (NO3-) is used as a nitrogen source, those acidic conditions can occur. Manganese is most available to plants when the soil pH is between 5.0 and 6.5. Soils with neutral or alkaline pH slow the solubility of manganese, so toxicities are less likely.
The most common symptoms of too much manganese look a lot like the symptoms of too much boron: 

• darkening of leaf veins, especially on older leaves
• leaf cupping
• older leaves exhibit pale, sunken, irregularly shaped patches of interveinal tissue, with patches closest to leaf margins turning black [these spots are more regularly spaced in boron toxicities]
• minor veins on the underside of leaves may appear black in older leaves
• soybean leaves crinkle and cup downward
• apple stems develop pustules in a condition called apple measles
• watermelon plants may wilt and drop leaves in only days, in a condition called sudden crash
• chlorosis occurs on younger leaves due to an induced iron deficiency

Too much manganese interferes with root growth and causes overall stunting, especially in alfalfa, small grains, and beans.


While magnesium is needed by all living things, too much magnesium can be very, very bad. At high doses, inhaled magnesium can lead to neurological damage called manganism, a condition similar to Parkinson’s disease. If you have to work with manganese, wear protective gear.

Bacterial and viral galls

Bacterial and viral galls develop because the bacteria or virus reprograms plant cells into producing more bacteria or viruses, or other supportive cells. When galls are found at or just below the soil level, it is, most likely, crown gall. Crown gall is a bacterial disease that can occur on blackberries, sunflowers, grapes, and roses, along with almond, apple, apricot, cherry, and pear trees.


Galls on roots may mean clubroot, a disease caused by an entirely separate group of parasites, known as Phytomyxea. Root galls may also mean the presence of beneficial, nitrogen fixing Rhizobium bacteria.


Galls have long been used in tanning, to make ink, and as astringents. Most galls contains high levels of tannic acid and resin. There even a few edible galls, but that is beyond my skill set.


Sometimes, what looks like a gall is actually caused by herbicide overspray.


Galls are most commonly formed when plant tissue is new and undifferentiated. This meristem tissue is most often seen in spring, so that’s when you should start looking for galls. Once gall development begins, the tissues have been reprogrammed and cannot go back to normal.


Gall management

In a word, you can’t. Insect and mite galls rarely harm plants and you can’t completely control these pests anyway. Once they are inside the plant, there is nothing you can spray or apply that will even reach them. Anyway, the gall is already in place. Fungal and bacterial galls may, possibly, if you are really lucky, and can time it perfectly, be prevented or reduced with fungicide treatments. Or not.

Damsel bug lifecycle

Young damsel bugs, or nymphs, look a lot like adults, which means they go through an incomplete metamorphosis. They have 5 developmental stages, or instars, before reaching adulthood. This process takes approximately 50 days. Adult females hide eggs by laying them inside plant tissue. Damsel bugs are most active in the Bay Area mid-June through mid-August, but they overwinter in ground cover and winter crops, such as alfalfa and many legumes. Remember, just because you don’t see them doesn’t mean they aren’t there.


Damsel bug prey

Like lady beetles and praying mantis, damsel bugs are generalists. This means they will eat whatever they can hold onto long enough to eat. Very often, those meals are aphids, armyworms, small caterpillars and caterpillar eggs, fleahoppers, leafhoppers, lygus bugs, mites, proba bugs, spider mites, and thrips. (Hooray for damsel bugs!) Of course, they will also eat beneficial big-eyed bugs and minute pirate bugs, and occasionally they will even eat plants, but their net result to the garden is still very positive.


In one study, it was estimated that a single adult damsel bug eats 42 moth larvae, 24 lygus bug nymphs, or 5 aphids every day. The same study estimated that a peak population of damsel bugs (283,000 bugs per acre) could consumer 12 million moth larvae, 6 million lygus bug nymphs, 1 million aphids, or some combination of those and other prey, every 24 hours. That’s some significant garden protection!


If you keep a hand lens in your pocket, you may be able to see a damsel bug up close one day.

Conditions that favor black root rot

Black root rot occurs most often in cool, moist conditions. It is most likely when temperatures are between 55° and 61°F. Black root rot can be spread by fungus gnats and shore flies, and it is more commonly found in alkaline soil, such as we have here in the Bay Area. Fungal spores can also be spread via splashing rain or irrigation water, or on infected flats, containers, and garden tools. Soggy soil, poor drainage, and too much fertilizer all contribute to the likelihood of these soil-borne fungi taking hold of your plants.


Preventing black root rot

Once infection has become well established, the plant is a goner, so prevention is your only course of action. [Always throw diseased plants in the trash bin.] In severe cases, soil solarization may be needed to prevent infecting the next plants installed in that location. In commercial nurseries, chemical fungicides are used as preventive measures only.


The best way to avoid black root rot is to provide plants with good drainage, avoid overwatering and excessive use of fertilizer, and control fungus gnat populations with yellow sticky paper. Acidifying the soil can help somewhat, but soil pH is very difficult to change without ongoing treatments. Crop rotation can also interrupt this disease cycle.


Remember, mulching with arborist wood chips is one of the best ways to improve soil structure and drainage, reducing the chance of black root rot finding its way to your garden.

Whether your garden is a backyard plot, a sidewalk strip, or containers on a balcony, the right tools can protect your hands, your back, and your plants. That being said, some of the tools advertised as “impossible to do without”, well, you can do without. Also, while there are plenty of power tools in the world of gardening, rototillers, chippers, and tractors are not needed by the home gardener. [I really appreciate having a chipper, though!] 


This guide provides an introduction to some of the more important garden tools, and introduces you to a few you may never have heard of before.


Pruners, shears, and loppers

If you only have one garden tool, make it a high quality bypass pruner. Pruners are used to clip away dead or diseased stems and leaves, to shape shrubs, trees, and espalier projects, and to harvest the fruits of our labors. Bypass pruners work much like scissors, in that the blades bypass each other to make a nice, clean cut. This makes it easier for plants to heal. Anvil pruners use a blade that cuts against a flat surface. This crushes plant material, but they are a good choice for cutting dead wood and woody stems. ​

Forks

Pitch forks and spading forks look like dinner forks, only bigger. Pitch forks, or hay forks, have round tines and are used for pitching hay and flipping compost. Spading forks have flat tines that are used to turn the soil and lift plants out of the ground. Garden forks are handheld tools that look like a hand, with the fingers curled downward. A gardening fork is used to break up soil and when weeding. There are also potato forks, border forks, and broad forks, which you can read more about at the Garden Tool Company.


Shovels and trowels

Even if you employ no-dig gardening, sooner or later, you are going to need a shovel. A shovel is used to turn the soil, break up dirt clods, move materials around, and prepare beds for planting. Long-handled shovels are easier on your back, and short-handled shovels are better when working in tight spaces.


There are two basic types of shovel: rounded end and square end. The end of a shovel is called its point. Round point shovels are used for digging. They usually feature a shelf for your foot, to provide extra digging power. Square point shovels are better used for moving all that valuable mulch around. Shovels with especially sharp cutting edges are called spades. Narrow spades, used for digging trenches and installing transplants, are called drain spades.

Hoes

Most hoes are long handled gardening tools with a small, thin metal blade, used to break up soil and in weeding. There are also handheld hoes, which are indispensable when it comes to getting to the root of problem weeds.

In addition to your standard, rectangular garden hoe, there are three other common garden hoes: the Warren hoe, the action hoe, and weeding hoes. The V-shaped Warren hoe is used primarily for digging furrows. The sharp-edged action hoe is a flattened circle used to cut weeds on both the push and pull strokes. There are actually several varieties of this type of how, which we will explore another day. Weeding hoes are double-headed in that they have a flat blade on one end and two pointed tips on the other end.

Rakes

There are 3 basic types of rakes used in the garden: leaf rakes, cultivars, and thatching rakes. Leaf rakes feature flexible tines, gathered at the top into a triangular shape, that cause minimal damage to lawns while collecting fallen leaves. Cultivators are the comb-shaped variety, with metal teeth, used to move mulch, rocks, and soil. When cultivars have a T-shape, it is called a flat rake. When the head is held in place with two curved steel supports, it is called a bow rake. Thatching rakes use short, sharp blade-shaped tines, held horizontally, to scratch the soil surface and to remove thatch from lawns.


Other tools

Other handy gardening tools include dibbles, brassica collars, moisture meters, a soil sampling tube, post hole diggers, edgers, stock panels, tree cages, tomato cages, canister sprayers, sticky barriers, brooms, tarps, rain barrels, knee pads… well, the list never really ends. Before adding to your tool collection, however, let’s take a look at common problems associated with garden tools.


Problems with garden tools

Dull tools are hard to work with and dirty tools can carry pests and diseases. If your tools are not well maintained, they can become dangerous to both you and your plants. A sharp, rusty edge can turn a small cut into a trip to the doctor’s office. Dull blades tear at plants, rather than making clean cuts. And if you don’t periodically sanitize your garden tools, well, you’re just asking for trouble. [Tools can be sanitized with bathroom cleaner or a solution of 1 part bleach and 9 parts water.]


There are a surprising number of mostly fungal diseases commonly spread by contact with infected tools. These diseases include Phytophthora tentaculata, Verticillium wilt, phytophthora root and crown rot, pink root, Fusarium wilt, Fusarium dieback, Fusarium crown and foot rot, eutypa dieback, stem blight, rust, rose rosette, peach leaf curl, onion white rot, mummy berry, karnal bunt, grey mold (also known as botrytis fruit rot and botrytis bunch rot), and cucumber mosaic. There are also bacterial diseases, such as angular leafspot, olive knot, black rot, crown gall, citrus blast (also known as bacterial blast or black pit), and blackleg that can be spread on contaminated tools. Conditions such as black spot, witches’ broom, bacterial wilt, and clubroot can also be spread by infected tools. Those tools can also carry vine mealybugs, nematodes, and San Jose scale to new plants. 


Remember, pests and plant diseases are not the only things that get carried on tools - herbicides, pesticides, and tetanus bacterium can hitch a ride just as easily. Keeping tools clean is one way to break disease triangles and prevent accidental exposure.


How to clean rusted tools

It happens. You leave a tool outside overnight, or you decide, as I did, that your garden tools look lovely, hanging up against the chicken coop. Unfortunately, in each case, this exposes metal tools to water. Metal plus water equals rust. Compounding that problem, putting tools away without cleaning them leaves soil and microbes in contact with the metal surface, which can also corrode the metal. Even if you are diligent about cleaning and protecting your garden tools, they will still need regular care to work properly and last. Following these steps will help your tools stay useful longer:

1. Scrub mud, grit, and debris from the tool and dry it as well as possible with an old towel, leaving in a protected place to dry completely overnight.
2. Use steel wool or a wire brush to remove any rust. If the rust is especially bad, you can use a rotary wire brush attachment on your drill for some super cleaning power.
3. Use a metal file to sharpen tools. This is a lot easier to do than many people realize. The file is not used heavily. Instead, it just takes a few angled swipes to refresh the cutting edge, removing nicks and burrs.
4. Oil metal tools after removing rust or sharpening. Many people use edible vegetable oil or mineral oil, while others opt for 3-in-1 and other petroleum-based oils.
5. Use sandpaper on wooden handles to keep them smooth and splinter-free, and oil them to prevent cracking.

So, what about those rarely heard of tools? How about a billhook? Or a sickle? Or a scythe? Scythes are those long-bladed tools you seeing being carried by Death or Father Time. If you ask my kids, they will tell you that scythes are implements of torture. This is due to my mother’s insistence that they help her mow a swath of path through her 97-acre Upstate New York farm one summer. Sickles are similar to scythes, but only smaller. 


Billhooks are similar to sickles, but with a wider blade and an even shorter handle. Used to pull brush and vines closer, and then cutting them, billhooks, block hooks, and brishing hooks are commonly used in vineyards and when pleaching. Pleaching is the art of building living fences.

Tree roots provide the life blood of the tree. If those roots start circling, corrective measures must be taken for the tree to survive

Ploughing or rototilling the area can reduce chickweed germination, but you may simply be trading one problem for another, as other weed seeds are brought closer to the surface. Maintaining a thick, vigorous lawn is another way to reduce the number of chickweed seedlings that make it to adulthood. Allowing your lawn to be taller than a putting green can reduce the amount of sunlight that reaches chickweed seedlings.


Before you completely write off common chickweed as undesirable, you need to know that it is also one of the preferred foods of the rare dainty sulphur moth (Nathalis iole).

How can you use soil test results? You could ask Mulder.


Garardus Johannes Mulder was a chemist who lived in the 1800s. Now, we have learned a lot about plant and soil science since the 1800’s, but Mulder came up with a chart that gives us some insight into how the minerals used by plants as food might interact. 

Before we learn how to use Mulder’s Chart, let’s review soil pH and nutrient absorption.


Nutrient absorption 

The 20 or so minerals used by plants as food are found in soil as ions. Ions are atoms and molecules that have either a positive or negative charge. These cations and anions, respectively, attach themselves to water molecules and are pulled into the plant by root hairs. The ability of a plant to pull those nutrients in depends largely on soil pH.

Soil pH

Soil pH ranges from 0 to 14, with lower numbers indicating acidity and higher numbers indicating alkalinity. Using the chart below, you can see that more nutrients are available, and there is greater microbial activity, when soil pH is between 6.0 and 7.0. Most plants can survive in soil pH from 5.2 to 7.8, but the narrower range allows plants to thrive. As anions and cations are pulled out of the soil, the soil pH changes, ever so slightly. This is why too much or too little of certain minerals in the soil may interfere with nutrient availability. This is where Mulder’s Chart comes in.


How to use Mulder’s Chart 

Looking at Mulder's Chart, you can see 11 essential plant nutrients and micronutrients arranged around a circle. Solid and dotted lines connect the nutrients, with arrows heading one way or the other. Solid lines indicate an “antagonistic” relationship, which means high levels of one nutrient leads to a problem absorbing the nutrient being pointed to, while dotted lines indicate a “synergistic” relationship.


For example, according to Mulder’s Chart, high levels of nitrogen may reduce a plant’s ability to absorb boron, copper, and potash, as seen by the solid lines pointing from nitrogen toward the other nutrients. In the same way, high levels of nitrogen may stimulate magnesium uptake, and high levels of molybdenum might stimulate plants into absorbing more nitrogen, as seen by the dotted “synergistic” lines. Like most things in life, though, it isn’t really that simple.


Soil chemistry

Until you have a soil test from a reputable laboratory, you cannot know what is in your soil. Soil test results provide an amazing snapshot of what is really going on “down there”. Your soil test results will include individual measurements of several plant nutrients, as well as a cation exchange capacity rating, which describes a soil's ability to hold nutrients.


According to Linda Chalker-Scott, associate professor of horticulture and extension specialist at Washington State University, “It makes sense from a strictly chemical point of view, but soils are also biological. Plants exude organic acids from their roots. Mycorrhizae can mobilize "immobile" nutrients. I find these types of charts way too simplistic for real world conditions.”


While there is certainly a limit to its usefulness, I do encourage you to apply Mulder’s Chart to your soil test results and compare those results to what you are seeing in your garden. It may give you an idea of where problems may be occurring, or it might just be a fun way to review your soil test.

Boron toxicity

Boron toxicity occurs when boron levels are at or above 1.8 ppm. Too much boron negatively impacts plant metabolism, and it reduces root and shoot development, chlorophyll production, rates of photosynthesis, and the lignin and suberin needed for structure and protection.


Toxic levels of boron can often be identified by looking at plant leaves. Too much boron will appear as either necrosis (death) or chlorosis (yellowing) of leaf tips and edges (margins). These damaged areas are believed to occur because the overabundance of boron interferes with several life processes, all at the same time. Unfortunately, these are the same symptoms as caused by magnesium deficiencies. [Can you say laboratory soil test?]

Adding extra boron is easy, when more is needed. Getting rid of excess boron requires more effort in the form of improved drainage through the addition of more organic material. Obviously, this takes time.

Boron deficiency

Insufficient or unavailable boron in the soil is the world’s most widespread micronutrient deficiency. It is a common problem in soils with low levels of organic matter (<1.5%). Boron deficiencies lead to reduced crop size and quality but symptoms can vary, depending on the crop:

• apples may display ‘water core’, areas that look frozen
• cabbages will have hollow areas in stems and distorted leaves
• cauliflower will show rough areas on stems, leafstalks and midribs, and brown patches on underdeveloped curds
• celeriac will envelop brown heart rot
• celery stalks will crack, showing reddish brown internal areas
• corn and soybeans will exhibit incomplete pollination
• pears will have hard brown flecks in the skin and new shoots will dieback in spring
• rutabagas and turnips show grey or brown concentric rings inside roots
• strawberries will be stunted and pale, with small yellowed, puckered leaves

Too much, too little, or no way for plants to get to the boron they need can all cause problems. Getting a laboratory soil test is the only way to know what’s eating your plants, or rather, what your plants are eating.

Autotoxicity is a form of chemical warfare found in the plant world, and it might be happening in your garden or landscape. Or, it might be an unsubstantiated biological process that looks great on paper, or works out well in a laboratory petri dish, but doesn’t hold as true in the field. 


In either case, it is good know what the concept claims, which parts have withstood the tests of time and science, and how it might impact your garden. Let’s start with basic competition for survival.


We know that plants compete with their neighbors for real estate and resources. Those resources include water, sunlight, nutrients, beneficial soil microbes, and access to pollinators. Over time, plants have found different ways to gain an edge over the local competition. Many weeds have evolved to grow faster, in order to find resources first, while other plants grow taller, to commandeer available sunlight. Other forms of competition occur when plants develop deeper or wider spreading roots, which can reach more food and water, or more flamboyant, heavily scented flowers, to increase pollination rates. In some cases, plants have evolved to use chemicals on their neighbors.


Chemical warfare among plants

​Oblivious to the Geneva Convention, some plants release chemicals through their roots, leaves, and stems that impact neighboring plants. When those chemicals affect other species, it is called allelopathy [al-el-ah-path-ee]. Allelopathic plants release chemicals that can either stimulate or inhibit the life processes of other plant species. When those chemicals only affect plants of the same species, it is called autotoxicity. Autotoxicity can only inhibit, and never stimulate, the growth or germination of plants of the same species. But why would a plant want to treat family members that way?


Family feud

The word ‘autotoxicity’ means ‘self-poison’ and it is used to describe the way some chemicals are believed to only negatively impact plants of the same species. From a survival perspective, on the surface, this might make sense. Members of a species all need the same resources to thrive. If there are too many of one species growing in the same place, those resources can be used up before any individual plant has time to reproduce, except that it isn’t that simple. Let’s take a closer look at which plants are said to be autotoxic and how autotoxicity is said to work.


Autotoxic plants

​Alfalfa is acknowledged as an autotoxic plant. How can this be, you might ask. Alfalfa is grown in immense fields, the same way corn, oats, and other similar crops are grown, with other alfalfa plants on every side, isn’t it? It is. But, underground, soon after alfalfa seeds germinate, seedlings start producing toxins that reduce germination and prevent the growth of root hairs in other alfalfa plants. Without root hairs, neighboring plants cannot absorb water or nutrients. So, why aren’t all the nearby alfalfa plants dead?

According to one Canadian study, several other edible plants are said to be impacted by autotoxicity. Their list includes rice, wheat, corn, soybeans, sugarcane, cucumber, ginger, muskmelon, watermelon, asparagus, tomatoes, citrus, tea, and coffee. The problem with the science behind autotoxicity lies in the fact that some of the chemicals cited as autotoxins, such as p-coumaric acid, are found in many other plants, with no ill effects. Also, in much of the current research, autotoxic chemicals are applied artificially, which may or may not involve all the steps that might occur in nature.


Autotoxic compost?

When we apply compost to an area of the garden or landscape, we are introducing a variety of chemicals. In the case of small home gardens, the diversity of plant materials found in a compost pile generally reduces any potential autotoxic affect to negligible levels. Using no-dig gardening and cutting used up plants off at soil level, rather than pulling them out by the roots, leaves these potentially autotoxic roots in the soil. This may or may not create a problem, but it is something to keep in mind.


Whether autotoxicity is a real problem or not, you now know more about it than most people. And remember, before you accept opinion as gospel, make sure there is enough good science behind it to make it worth your time and effort.

Yeasts have been around for hundreds of millions of years. In many ways, yeasts and other fungi are a lot like plants, but they are different in many ways, too.


Yeast vs. plant cells

Yeast cells are smaller than plant cells. While plant cells can become leaf, stem, fruit, or root cells, yeast cells remain the same one-celled creature. Like plant cells, yeast cells have a cell wall, but it is not made out of cellulose. Both yeast and plant cells have membranes, but they are made out of different materials. Yeast cells do not have chlorophyll-producing chloroplasts, either, which is why they do not use sunlight to make food. Inside a plant cell, you can find food stored as a starch, whereas yeasts store food as sugar. 


Other common fungi include mushrooms and molds. The yeast you buy in the store to make bread, beer, or wine is called Saccharomyces cerevisiae.


How do yeasts grow?

Yeasts do not require sunlight to grow. Yeasts feed on dead, decaying matter, making them saprophytes. They are also parasites, which makes them heterotrophs. Instead of using the sun’s energy to generate food, fungi absorb carbon, in the form of sugars, organic acids, and other easy-to-digest carbon-based edibles from their hosts. This is why you will often see fungi growing on the skins of apples, grapes, or peaches. Yeasts grow best when the environment has a neutral or slightly acidic pH. ​

Harmful yeasts in the garden

Yeasts love to eat sugar. As such, they can spoil fruits and vegetables before you ever get a chance to enjoy them. Yeasts can grow on almonds, pineapples, lettuces, and pretty much anything else you decide to grow. Peach leaf curl is also caused by a yeast. That being said, yeasts actually perform many beneficial services to your garden.

Like their cousins, the aphids, adelgids pierce vascular bundles to suck out nutrient rich fluids. While mature, healthy trees can withstand a mild adelgid infestation, saplings, young trees, and unhealthy trees can be killed by this tiny, soft-bodied pest.


Adelgid species

Scientists are still trying to nail down adelgid classification. There are 50 known species, all of which are native to the northern hemisphere, though several invasive species have made their way into the southern hemisphere. The most commonly found adelgids in California include the invasive balsam wooly adelgid (from Europe), the Cooley spruce gall adelgid (Adelges cooleyi Gillette), and pine adelgids.


Adelgids are commonly found on stone pine and other conifer species, such as pine and spruce. Depending on the host plant, the pests are commonly known as “pine aphids” or “spruce aphids”, respectively, even though they are not actually aphids. [Thanks to my friend, Chuck, I now know that adelgids are also found on apple trees. Thanks, Chuck!]

Damage caused by potato tuberworms

Young potato tuberworm larvae might burrow through leaves and stems, causing stunting and reduced crop size. As feeding and tunneling continue, the tuberworms head for their favorite food: your potatoes. Webbing and frass (bug poop) deposits can be seen at entry holes, normally found at the eyes of a potato. While other pesky tunneling insects, such as wireworms and leaf miners, tend to keep their tunnels neat and tidy, potato tuberworms are slobs. Those dark tunnels are filled with excrement.


Controlling potato tuberworms

Row covers can be used to prevent adult moths from laying eggs on your potato plants. The deeper your potatoes are growing, the more difficult it is for tuberworms to get to them, so selecting a deep growing variety is helpful if you know tuberworms are around. Also, avoid furrow irrigation, which can cause cracks in the soil. These cracks are used as elevators to lower soil levels by tuberworms.  Research has shown that insecticides do not prevent potato tuberworm infestations when erosion or soil cracks are present, or when potatoes are left in the ground longer than is necessary. Finally, harvest potatoes as soon as they are ready. Infested potatoes should be thrown in the trash and not added to the compost pile. Heavy infestations can be treated with spinosad.

How to prevent potato scab

Being a seed and soil borne bacteria, potato scab is best prevented by manipulating soil moisture, soil texture, and soil pH, and planting healthy stock You won’t get rid of the bacteria completely, but you can significantly reduce their numbers with these tips:

• Resistant varieties  Plant resistant varieties to reduce the chance of initial infection.
• Seed potatoes Plant disease-free seed potatoes.
• Soil moisture High levels of soil moisture during early growth appear to stimulate populations of competing bacteria, slowing the development of potato scab. Of course, too much soil moisture can lead to other problems, such as fungal disease and rot. 
• Soil amendments Since the bacteria responsible for potato scab are involved with breaking down organic matter, adding aged compost while potatoes are developing is not a good idea. [Put that treatment off until after harvesting is completed.] 
• Soil texture The potato scab bacteria seems to prefer gritty, sandier soil, over loamy clay.
• Soil pH Potato scab bacteria are suppressed in acidic soil, with a soil pH at or below 5.2.
• Crop rotation Crop rotation can be used with grains or other non host species, such as corn or alfalfa, to reduce S. scabies populations. Do not rotate with other root crops, such as beets, turnips, parsnips, carrots, radishes, rutabagas, as these crops are also susceptible to scab. Rotating with spinach, cabbage, and red clover should also be avoided.

You can still eat potatoes infected with potato scab, but you should probably cut out the lesions and toss them in the trash.

Eventually, the once green, bushy potato plant looks more like a pitiful yellow Christmas tree. [If chlorosis is spotty and leaf rosetting is not present, the problem is more likely to be calico virus.] If potato psyllids are removed from the plant, the condition will stop progressing. 


Potato psyllids are also carriers of another condition, known as zebra chip. Zebra chip is a bacterial disease that causes potatoes to store sugar, rather than starch. That might sound like a great idea for a new dessert food, but the presence of sugars cause ugly brown lines across the length of the potato. When cooked, these brown lines turn black, hence the name. This condition reduces crop size by 20 to 50%. Healthy appearing potatoes from plants affected by zebra chip are more likely to sprout while in storage.


Managing potato psyllids

You can’t control potato psyllids if you don’t know where they are. The first step to managing potato psyllids is to use yellow sticky traps. You can buy these at any garden center, or you can make your own with some yellow paperboard and sticky barrier goo. You should also inspect the undersides of leaves, looking for nymphs. While you’re at it, you should probably check the underside of any nearby bean or pepper plants, as these may also become infested.


In commercially grown potato fields, where potato psyllid is known to occur, a type of systemic neonicotinoid neurotoxin, called imidacloprid, is applied. [While not yet noted in California, resistance to imidacloprid has been documented in Texas.] Organic growers, like myself, use spinosad.


Because potato psyllids are not native to California, our local team of predators, which include lady beetles, lacewing larvae, and minute pirate bugs, have not been very effective at controlling this pest. Not yet, anyway.