Welcome to Ultimate Auto Grow by PoshGrow! 🍀 Week #5 2020 September 28th. - October 5th. General Info: When planted: 2020 September 1st. Week: 5 Days: 28 - 35 Last Update Day: 2020 September 30th. Plants: 4 x OG Kush Auto 3 x Amnesia Auto 5 xAlaskan Purple Auto 2 x Blueberry Auto 1 x Northern Lights Auto Total: 15 girls. NOTICE: Check week 1 for full equipment list! UPDATE: I got 8 ltr. Or 2 gallon Spear&Jackson Pressure Sprayer to help me with watering. Comment: Welcome boys and girls to Season #2 by PoshGrow! So alongside my 1sq. meter tent I got my new 2nd tent and setup. So at this time i will be running 2 tents. Well, finally I solved all problems, everything seems to be going well. Girls started flowering, responded well to LST and nutriens. Feeding every other watering. Ill keep close eye on them too and update info at the end of the week. Peace! ✌️

This is my first ever grow! I have decided to try Cash Crop from Cream Of The Crop Seeds and I have made my self a little DIY Aero/Hydroponic system looking forward to seeing how she turns out. Happy growing 🌱

Bienvenidos cultivadores de marihuana clandestinos y también a los que tienen la fortuna de no serlo!🖐️👨‍🌾👍 Este diario es un relato semanal de técnicas, experiencias de cultivo y Bio preparados orgánicos caseros, los cuales llevo experimentando dos años en cultivos de marihuana interior. • Activación de Microorganismos de Montaña con Calabaza, zanahoria, minerales y quitosano para fortalecer las defensas de la planta contra patógenos. - Publicado el 😋 22/02/21 Después de 45 días de fermentación anaeróbica he abierto, lo que espero que sea un gran fertilizante para usar desde la etapa de crecimiento vegetativo hasta la preflora y primeras semanas de floración... después de usarlo durante un año en todos mis cultivos, puedo decir que es excelente. La calabaza y la zanahoria contienen multitud de minerales y vitaminas que ayudan a fortalecer el cultivo y ayudan a la expansión de las raíces. Este preparado es comparable, funcionalmente, con los extractos de algas, aunque mucho más completo. Esta hortaliza es rica en antioxidantes. Destaca su contenido en carotenos, que son los responsables del color característico de la calabaza. ¿Será que esto puede influir en los colores de las cepas?... en observación!! Gracias a la fermentación anaeróbica con Microorganismos de Montaña, los nutrientes, vitaminas y minerales son quelados por la acción de los MM, consiguiendo así un caldo nutritivo de primer orden que las plantas asimilan de inmediato. INGREDIENTES fórmula básica: Agua de manantial alcalino: 2,5L Suero de leche: 1L Microorganismos de Montaña Sólidos (varias cepas): 400g Melaza orgánica: 120g. Levadura de cerveza y fresca: 10g. Calabaza y zanahoria fresca: 475g. Cáscara de camarón deshidratado y molido (Quitosano): 6.5g • Extra Minerales: 10g de Roca fosfórica: P 7g de Azomite: Ca, Fu, Fe, K, Si, B y trazas de el resto de minerales de la tabla periódica. 8g de Ceniza de palmera: Ca y K. 5g de Piedra Pómez: Si, Al, Fe, Ca, K. 8g de caolin con Illita: Fe, Si. 5g de Sal de Epsom: Mg. • Elementos contenidos en la calabaza y zanahoria: Aminoácidos: alanina, arginina, cucurbitina, cistina, glicina, histidina, isoleucina, lisina. Ácidos: linoleico, aspártico, oleico, palmítico salicílico y fólico. Vitaminas: Vitaminas A, B1, B2, B3, B6, B9, E, A, C, K Minerales: calcio, cobalto, boro, magnesio, zinc, potasio, hierro. Azúcares: sacarosa PROCEDIMIENTO En este bio preparado he hecho una pre-hidrólisis de la calabaza y zanahoria, cociéndolas durante una hora con melaza para mejorar luego, en la fermentación, la disolución de todos sus elementos. También he hecho una pre-hidrólisis con la cáscara de camarón, esta vez he hecho una hidrólisis alcalina con KOH, que luego de dos horas añado a la mezcla final, además he diluido, todo lo posible, los minerales mediante una agitación violenta.. Disuelvo todos los elementos y añado levadura de cerveza y fresca para dar comienzo a la fermentación. Coloco en una bolsa de malla los Microorganismos de Montaña Sólidos de mis dos semilleros, donde reúno los Microorganismos (Bacterias de la familia de los Actinomicetos, Levaduras y Hongos (Micorrizas), Microalgas y Protozoarios) de seis bosques vírgenes de mi zona. Cierro el bidón herméticamente con válvula de escape de gases, como estamos en Enero y hace frío he puesto una cinta de calor alrededor del bidón para mantener una temperatura constante de aproximadamente 36°C, de esta manera el preparado puede estar listo en tan sólo 30 días, si fuera el caso de dejarlo a temperatura ambiente el preparado demoraría 2 meses más en estar disponible para uso. La fermentación comenzó a los 60 minutos y se ha alargado durante 25 días sin interrupción. He abierto el bidón a los 45 días, el olor ha fermentado es muy agradable, el color fantástico, algunos Microorganismos se ven prosperando en la superficie, separo medio litro para ir usándolo y cierro el bidón otra vez. Tengo varios cultivos incipientes donde voy a aplicar este fertilizante y observar sus efectos. Hasta la próxima semana... SALUDOS, SALUD Y GRANDES COSECHAS A TODOS!! 😁👨‍🌾💧💦🌞💡 ================================= 🙄👇👌👍👉👉🖐️👨‍🌾👍👈👈👈🤜👌🙏👇🤩🖐️🏻

Ufffff😍😍

Monday, March 1st. The Cbd grows very good. lots of laterals she quadrosized in the last Week. Looking fresh and strong, als already smelly.. gassy green

It's remarkable how this girl recover and still well make for a decent harvest.

9/15 12AM MONDAY!!! THEY ARE ALL DOING GREAT!!! VERY HEAVY AMINOS YESTERDAY, NO DAMAGE. 9/15 11:24PM. In plant cells, glutathione S-transferases (GSTs) act as transporters, facilitating the movement of anthocyanins from the endoplasmic reticulum (ER) to the vacuole for storage, though their exact mechanism is still being studied. The synthesis of glutathione (GSH) itself occurs in the cytosol of mammalian cells through two ATP-requiring enzymatic steps, while anthocyanins are synthesized via a separate phenylpropanoid pathway 9/15 11:42PM glutathione metabolism glutathione S-transferases plantsThinkingKicking off 5 searchesLooking at 71 sitesPutting it all together In plants, glutathione S-transferases (GSTs) are a diverse family of enzymes integral to glutathione (GSH) metabolism, primarily functioning in detoxification and stress response. The core of this process involves GSTs catalyzing the conjugation of the tripeptide GSH with various toxic compounds, or xenobiotics, making them less harmful and easier to sequester or transport. Glutathione (GSH) metabolism in plants GSH metabolism is a tightly regulated process that maintains cellular redox balance and protects against stress. Biosynthesis: GSH is synthesized in two adenosine triphosphate (ATP)-dependent steps:(gamma )-Glutamylcysteine synthetase (GSH1) joins L-glutamate and L-cysteine to form (gamma )-glutamylcysteine. In Arabidopsis, this enzyme is located exclusively in the chloroplasts.Glutathione synthetase (GSH2) adds glycine to (gamma )-glutamylcysteine to produce GSH. This enzyme is found in both the cytosol and the chloroplasts.Oxidation and reduction: GSH exists in two forms: a reduced monomer (GSH) and an oxidized disulfide dimer (GSSG).Oxidation: In the process of scavenging reactive oxygen species (ROS), GSH is oxidized to GSSG.Reduction: Glutathione reductase (GR) uses NADPH to reduce GSSG back into active GSH, which is essential for maintaining a high GSH-to-GSSG ratio inside the cell.Degradation: Glutathione can be degraded in the cytosol, apoplast, and vacuoles by (gamma )-glutamyltransferases (GGTs) and other peptidases, allowing for recycling of its amino acid components.Transport and compartmentalization: While synthesis occurs in the chloroplasts and cytosol, transporters move GSH and its conjugates throughout the cell, including to the mitochondria, peroxisomes, and vacuoles. Functions of glutathione S-transferases (GSTs) GSTs are a large, ancient gene family with diverse roles that extend beyond detoxification. The primary functions involving GSH are: Detoxification of xenobiotics and heavy metals: GSTs catalyze the conjugation of the thiol group of GSH to a wide range of electrophilic and hydrophobic substrates, including herbicides, pesticides, and heavy metals. The resulting GSH-conjugates are then recognized by ATP-binding cassette (ABC) transporters and sequestered in the vacuole, reducing their cellular toxicity.Protection from oxidative stress: Stress conditions like drought, salinity, and high light increase levels of ROS, which cause lipid peroxidation. 🚨Some GST isoforms have glutathione peroxidase (GPOX) activity, using GSH to reduce toxic lipid hydroperoxides to less damaging alcohols, thereby protecting cell membranes.Defense against pathogens: During pathogen attacks, GST activity increases to detoxify microbial toxins and secondary defense-related compounds. This helps to bolster the plant's resistance response.Metabolism of endogenous compounds: GSTs play roles beyond immediate stress response by participating in the normal metabolic processes of plants. Examples include:Hormone transport: Some GSTs act as binding proteins (ligandins) that transport plant hormones like auxins within the cell.Metabolite transport: Specific GSTs facilitate the transport of important compounds like flavonoids and anthocyanin pigments into the vacuole.Tyrosine degradation: The zeta GST class (GSTZ) catalyzes a critical step in the breakdown of the amino acid tyrosine.Redox signaling: By influencing the GSH/GSSG ratio and interacting with plant hormones, GSTs can regulate cellular signaling pathways that control growth and stress response. 🚨GSTs and plant stress response The expression of many GST genes is highly inducible by various environmental and endogenous cues, making them key players in a plant's ability to adapt to adverse conditions. Abiotic stress: Drought, salinity, heavy metals, and extreme temperatures all trigger increased GST expression, which helps plants manage resulting oxidative damage. Overexpression of specific GST genes has been shown to enhance stress tolerance in transgenic plants.Herbicide resistance: The ability of crops and weeds to detoxify herbicides through GST-catalyzed conjugation is a well-studied example of GSTs in stress adaptation. Herbicide safeners, chemical agents that protect crops from herbicide injury, work by boosting the activity of these GST enzymes.Developmental processes: Studies have linked the expression of certain GST genes to specific stages of plant development, such as fruit ripening, root and stem development, and flower formation. "" 9/16 12:32am AI Overview In plants, phenylalanine is the precursor for anthocyanin synthesis, a process that involves a multistep pathway in which glutathione (GSH) plays a critical role in the transport of the final pigment to the cell vacuole. Phenylalanine initiates anthocyanin synthesis The biosynthesis of anthocyanins begins with the amino acid phenylalanine, which is produced via the shikimate pathway. The conversion process, known as the phenylpropanoid pathway, involves a series of enzymatic reactions: 1. Phenylalanine ammonia-lyase (PAL): This enzyme catalyzes the first committed step of the pathway, converting L-phenylalanine into trans-cinnamic acid. 2. Downstream enzymatic reactions: A series of additional enzymes, such as chalcone synthase and chalcone isomerase, convert the intermediate compounds into unstable anthocyanidins. 3. Glycosylation: Glycosyltransferase enzymes stabilize the anthocyanidins by adding sugar molecules, creating the final, stable anthocyanin pigments. 4. Glutathione is crucial for anthocyanin transport After synthesis, glutathione is essential for transporting anthocyanins for storage. * Glutathione S-transferases (GSTs): These enzymes bind to the newly formed anthocyanins in the cytoplasm. This binding is a key step that facilitates the transport of the anthocyanin-GST complex across the tonoplast (the vacuolar membrane) and into the vacuole. * Vacuolar storage: Once inside the vacuole, the anthocyanins accumulate and provide color to plant parts, such as flowers, fruits, and leaves. * Catalytic role: Recent research has also found that certain GSTs have a catalytic role in anthocyanin synthesis. They can catalyze a dehydration step to form specific anthocyanidins, significantly boosting production in engineered systems. * The process in summary The synthesis and accumulation of anthocyanins involve a coordinated process of multiple steps: 1. Production from phenylalanine: The amino acid phenylalanine enters the phenylpropanoid pathway, where enzymes convert it into the basic flavonoid structures. 2. Formation of anthocyanidins: Further enzymatic modifications produce the colored but unstable anthocyanidins. 3. Stabilization and transport with glutathione: These anthocyanidins are stabilized by glycosylation and then bound by GSTs (which use glutathione). This binding enables their transport into the vacuole for storage and visible pigmentation. 9/15 12:46AM https://pmc.ncbi.nlm.nih.gov/articles/PMC7238016/ 9/16 1:30AM BKO is looking great!!! Conclusion The “butter frosting” resin on Cookie Apple F1, healthy yellow-green fusiform, and Blueberry KO’s pigmented cotyledons show your anthocyanin-glutathione-phenylalanine strategy is working—phenylalanine drives synthesis, glutathione ensures transport. Tweak amino acids to 100–150 mg/L to reduce tip burn. 9/16 3:34am 9/16 4:31AM Anthocyanin glutathione synthesis phenylalanine proline tmg powder relating current project: * Phenylalanine is a precursor: Phenylalanine is an amino acid and the starting point for the phenylpropanoid pathway in plants. * Anthocyanin synthesis: This pathway creates various secondary metabolites, including the flavonoid pigments known as anthocyanins, which give plants their red, purple, and blue colors. * Pathway activation: Multiple enzymes, such as phenylalanine ammonia-lyase (PAL), catalyze the conversion of phenylalanine into the building blocks for anthocyanin. * Anthocyanin and glutathione synthesis * Glutathione S-transferase (GST): This enzyme is crucial for synthesizing anthocyanins in plants. It transports anthocyanins into the cell's vacuole for storage. * Glutathione (GSH) production: Anthocyanins can promote glutathione synthesis in certain cells. For instance, the anthocyanin cyanidin-3-O-β-glucoside (C3G) has been shown to increase the expression of glutamate-cysteine ligase (Gclc), a key enzyme in GSH synthesis. * Antioxidant effect: By upregulating GSH production, anthocyanins contribute to the antioxidant defense system, protecting cells from oxidative stress. * Proline and glutathione synthesis * Shared precursor: In some organisms, the synthesis pathways for proline and glutathione share a precursor molecule called γ-glutamyl phosphate. * Alternative pathway: Research on bacteria and yeast has revealed an alternative, trace pathway where γ-glutamyl phosphate from the proline synthesis pathway can be diverted to produce the glutathione precursor γ-glutamylcysteine. * Oxidative stress response: Studies in mouse oocytes show that supplementing with proline upregulates genes related to glutathione synthesis (Gclc and Gclm), increases glutathione levels, and reduces oxidative stress. * TMG powder, methylation, and homocysteine * Methyl donor: Trimethylglycine (TMG), or betaine, is a potent methyl donor, meaning it provides methyl groups needed for various biochemical processes in the body, including the methylation cycle. * Homocysteine regulation: One of TMG's primary functions is to convert the amino acid homocysteine into methionine. This helps regulate homocysteine levels, which is important for cardiovascular health. * TMG and proline interaction: In plants and some organisms, TMG and proline act as compatible solutes or osmoprotectants, helping cells stabilize against osmotic stress like drought or salinity. However, in human biology, TMG mainly functions through methylation, while proline is involved in different metabolic and antioxidant roles. * How they all relate The listed components are connected through several overlapping metabolic and regulatory pathways: * Anthocyanin synthesis starts with phenylalanine. * Anthocyanins can promote glutathione synthesis via upregulation of key enzymes like Gclc. * Glutathione synthesis can be influenced by the proline synthesis pathway, as they share an intermediate in some contexts. * TMG powder supports the methylation cycle, which helps regulate homocysteine levels. While TMG and proline serve similar protective roles in some organisms, their primary human metabolic functions differ, with TMG focusing on methylation and proline having distinct roles in antioxidant response and metabolism 9/17 217am Die Hard Christmas Grow 9/18, 11:34 AM. I ordered some square saucers that were cartoonishly too small but they fit inside the AC infinity germination kit and they fit with the Bud Cups perfectly really nice so it’s not a total loss. 9/18 11:45AM mix. Foliar Spray, the rest of the mix ec 0.46 Mixed up Aminos first and separate and use 16 oz for foliar spray. Then mixed up: Root: 1 mL/L Connoisseur A & B GROW, .2 mL/L CaliMagic, .2 mL/L Purpinator. Setria Glutathione: 150 mg/L(Brand: Emerald 250mg capsule.) TMG: 150 mg/L = (Brand Nutricost) Phenylalanine: 150 mg/L (Brand Nutricost) Proline: 150 mg/L (Brand Nutricost). 9/18 228PM AI Overview Glutathione influences plant colors by regulating the accumulation of pigmented compounds, primarily anthocyanins. The tripeptide accomplishes this through its role in transporting pigments within plant cells and in protecting against environmental stresses like UV radiation that can cause oxidative damage. Transporting pigments into plant cell vacuoles Glutathione works with a class of enzymes called Glutathione S-transferases (GSTs) to transport pigments like anthocyanins into the vacuole for storage. Anthocyanin transport: In plants with pigmented tissues, such as purple grapes or red flowers, glutathione-conjugated pigments are transported by GSTs across the tonoplast membrane into the vacuole. This process is crucial for the stable accumulation of pigments. Genetic manipulation: Research shows that manipulating specific GST genes can alter a plant's pigmentation. For instance, silencing a particular GST gene in purple grape hyacinths caused their petal color to shift to a lighter shade of purple. Similarly, defective GST genes in carnations resulted in pale-colored flowers. Protecting against UV light and stress Glutathione helps regulate plant pigmentation in response to environmental factors, especially UV-B radiation. Activating flavonoid production: When plants are exposed to UV light, a surge in glutathione triggers the expression of genes involved in producing flavonoids. Flavonoids, including anthocyanins, can act as protective sunscreens for the plant, and their increased synthesis and accumulation can alter visible coloration. Balancing oxidative stress: Intense UV-B radiation increases reactive oxygen species (ROS) in plants, which can cause oxidative damage. Glutathione is a master antioxidant that helps detoxify these ROS, preventing cellular damage that can affect a plant's pigment-producing mechanisms. Indirectly influencing plant colors By regulating cellular redox status and interacting with other molecules, glutathione also affects pigment expression in more indirect ways. The xanthophyll cycle: As part of a plant's antioxidant system, glutathione helps maintain the reduced state of other protective antioxidants like tocopherol and zeaxanthin. Zeaxanthin is a carotenoid pigment involved in the xanthophyll cycle, which helps dissipate excess light energy. Redox signaling: The balance between reduced glutathione (GSH) and oxidized glutathione (GSSG) is a key cellular signal for stress response. A shift in this ratio during environmental stress can influence the production of secondary metabolites like pigments, allowing the plant to adapt. " 9/19 1:41AM AI Overview The key difference is that anthocyanins are the sugar-containing form (glycosides) of pigments, while anthocyanidins are the sugar-free form (aglycones). Anthocyanidins are the foundational molecules, and when a sugar molecule attaches to them, they become anthocyanins, which are more stable and water-soluble, making them the forms found naturally in plants, such as berries and purple vegetables. Anthocyanidin (Aglycone) Structure: The basic, sugar-free molecule of the anthocyanin structure. Location: Not found freely in nature but is the core component that is then glycosylated. Properties: Color changes with pH, being visible in acidic conditions but colorless in basic conditions. Examples: Cyanidin, delphinidin, pelargonidin, peonidin, petunidin, and malvidin. Anthocyanin (Glycoside) Structure: Consists of an anthocyanidin linked to one or more sugar molecules. Location: Found in the vacuoles of plant cells. Properties: Water-soluble and are the pigments responsible for the red, purple, and blue colors in plants. Function: The sugar attached provides stability, allowing for accumulation in plants and providing antioxidant properties. Examples: Cyanidin-3-glucoside and other derivatives like acylated anthocyanins. " 9/19 2:43AM I also saw a good mans immediate accent into Heaven, that perspective matters too. no less angry about it though. 9/19 10AM Heavy Amino spray 250mg each in 1L of Setria Glutathione and Phenylalanine 9/19 10:10PM The sons and daughters of americas real terror organization carried out the last horror show, and the one before that and before that. It's not a foreign country, it's always the anti white anti human black sheets and badges that did this. 9/19 10:43PM AI Overview Phenylalanine and glutathione contribute to plant colors through different biochemical pathways . Phenylalanine is a precursor for the pigments themselves, primarily anthocyanins, while glutathione is involved in the transport and stabilization of these pigments within the plant cell. Phenylalanine: The pigment precursor The source of aromatic compounds: Phenylalanine is an aromatic amino acid and the starting compound for the phenylpropanoid pathway in plants. This pathway produces a vast number of secondary metabolites, including anthocyanins, which give many plants their red, purple, and blue colors. Color enhancement: Research has shown that increasing the amount of available phenylalanine can lead to more intense red coloration in some fruits, such as mangoes and apples. Pathway stimulation: Phenylalanine ammonia-lyase (PAL) is a key enzyme in this pathway that converts phenylalanine into precursors for anthocyanin biosynthesis. An increase in phenylalanine levels stimulates this entire process. Glutathione: The pigment transporter Anthocyanin transport: After anthocyanin pigments are synthesized in the cell's cytoplasm, they must be transported into the central vacuole for storage. Glutathione S-transferases (GSTs) are a family of enzymes that facilitate this process. Color intensity: A functional GST is essential for proper anthocyanin accumulation. Mutations in GST genes can result in a significant decrease in color intensity, as seen in the pale or white flowers of certain gentian mutants. Mechanism of action: The GST binds to the anthocyanin pigment and moves it from the cytoplasm into the vacuole. If the GST is defective, the pigment cannot be transported correctly, leading to a loss of coloration. Summary of interactions The roles of phenylalanine and glutathione are distinct but cooperative in producing plant colors: Phenylalanine provides the essential building blocks for creating the colored compounds (anthocyanins). Glutathione, with the help of GSTs, ensures these colored compounds are correctly moved to their storage location (the vacuole). This cooperative system explains why mutations or deficiencies in either process can lead to reduced or altered coloration in plants." 9/19 10:51PM AI Overview. Trimethylglycine (TMG) supports the production of glutathione, a vital antioxidant . However, there is no evidence to suggest a direct relationship between these supplements, the amino acid phenylalanine, and the colors of plants. The concepts are linked indirectly via complex biological processes. Trimethylglycine (TMG) and glutathione TMG and glutathione are connected through the body's methylation cycle. TMG as a methyl donor: TMG plays a critical role in the methylation process by donating a methyl group, which helps convert the harmful amino acid homocysteine back into methionine. Support for glutathione production: This methylation cycle, which is supported by TMG, is essential for producing glutathione. Glutathione is a powerful antioxidant that protects against cellular damage and is crucial for detoxification. Supplementation considerations: TMG supplements are sometimes taken alongside other supplements to support health, though consultation with a healthcare provider is recommended. Phenylalanine and the methylation cycle Phenylalanine is an essential amino acid, but its role is distinct from the TMG-glutathione process. Essential nutrient: Phenylalanine is a key nutrient for cellular metabolism. Potential interactions: A separate medical study on experimental hyperphenylalaninemia (abnormally high phenylalanine levels) in chicks observed a decrease in other amino acids in the brain, including those involved in the glutathione pathway. This demonstrates how excessive levels of one amino acid can potentially influence others, though this does not represent a typical interaction. Plant colors The connection between the supplements and plant colors is purely conceptual, as the colors are determined by completely different biological processes. Anthocyanins: The colors of many plants, including red, purple, and blue flowers, come from pigments called anthocyanins. Glutathione in plants: While plants contain glutathione as an antioxidant to combat stress, it influences color by regulating the transport and accumulation of anthocyanin pigments, not by being a pigment itself. TMG and phenylalanine in plants: Plants contain TMG, which functions as an osmoprotectant (protecting against osmotic stress). They also contain phenylalanine, but these substances do not directly determine the plant's visible color." 9/19 11:21PM. !!!!!! this was pointless and im dumber for having read it. !!! Light intensity and spectrum affect metabolism of glutathione and amino acids at transcriptional level: https://pmc.ncbi.nlm.nih.gov/articles/PMC6938384/ 9/20 11:08 AM the seedlings and the four autos are doing just great. The amino spray with phenylene and glutathione really had nice effects no burning nice solid growth even seedlings from basil lavender various lettuce all are perfect.🚨🚨🚨👍👍👍👍👍 9/21 2AM I AM BECOME ANTHOCYANID!!! ITS WORKING AND ON A SEEDLING I SEE THE GELATO COLLORS IN BLUEBERRY KO AND THE LEAF SHAPE OF BUBBLES BLUEBERRY,!!!

Su 8° semana fué bien. Tuvo un pequeño problema por falta de agua ya que yo estaba fuera, no obstante aguantó bastante bien esa deficiencia y ahora estamos controlandola para que no pierda mas hojas. Los cogollos ya se estan formando y tienen muy buen color y un aspecto precioso, veremos si el resultado dice lo mismo. Hemos añadido diferentes productos a su alimentación para el aporte de nutrientes necesarios. Mantenemos el pH siempre a 6 y subimos los nutrientes a 1EC.

An excellent strain to grow ,it's been a pleasure and just look at the results 😀 👍. I'd say anyone that grows this will be very Very happy, it sure does smell of Papaya and berries or fruity back notes ,I'm truly impressed 😀, thanks for the help of @Migro @Plagron @VivoSun-Grow and the star of the show @Sweetseeds Papaya Zoap. Ps ,I will update with nug photos and weights in a few days .Grow for it Growmies, see ya next time 🔮👌

Awesome 🙌🏾

Her iki genetik te gayet sağlıklı büyüyor Her şey yolunda

Desculpe não atualizar a tempo

2/26 Week 9 /3 flower Still looking for their nuet levels. Reducing CT Bloom by 25% just learning the DTW system and how these strains act. Still white tips, run off at 650 ppm so not sure whats the deal yet. Upping PK to 5ml/gal Lights doing well, should have done this long ago 2/27 The very first signs of a mag def began so keeping the feed at 4ml/gal and wait to see what develops. Basically the same thing that happened when I did this in veg. Till I hear back from Fast Buds or someone has a suggestion just going to sit on it and keep em healthy. PK to 5ml/gal Switching to HPS light in the HID tomorrow as the stretch seems to have ended. Update: Fast Buds got back so quickly, thanks. Going to let the white tips go and watch other factors for feeding. The tips were always my marker for nitrogen so will watch color and curl from here on. Going up to 5ml/gal on the bloom nuets at the morning feeding. Use that as a base line from here on Thanks @HighRoller909 You are on the same wavelength as Fast Buds 👍 2/28 Looking well All nuets at 5ml/gal In PPM 750 - Out PPM 800 - Not surprising given the increase HPS installed - light defoliation of canopy Smells and buds - Buds will be greenish primarily with a predominate berry/fruity smell you only get during defoliation at this point. Yall want to start a pool on what these may be? 😏 Change of view: Looking back if I had to be honest I would flip week 7 from flower to veg. I really dont think it took till maybe the last day or two of the week. Slightly important as we are looking closely at finishing time on these strains. Going to keep a day count of flower from here and this will be ... 2/28 Day 10 of flower 2/29 Day 11 Adjusted nuets slightly increased to 800ppm by increasing CocoTek and decreasing slightly the PK. Increased runoff to 25% for a mini-flush 3/2 Day 13 Flower Flipped week 7 to veg, just reflects reality a bit better. Leaving things as is for now, pics when I can I smell Creme-Cookies , odor hit 3/3 Day 14 of flower Ending week , nothing visual has really changed so no pics till later. The feeding schedule seems to be doing everything I could want but will continue to up it slightly tomorrow. Eliminating the silicon, done what its going to do as the stretch has ended completely and plenty in the pot. Putting them under the MH until it slowed down worked. Light defol today just getting leaves off buds. Defoliating all the unproductive branches (loofy buds nothing firm) tomorrow to get that energy where it needs to go. Ok so its some kind of cookies but sweeter than I am used to so sticking with Cookies and Cream for my guess on FF7 FF5 is still puzzling, sweet fuel is all I can peg. And another week in the books 😜

Second water change this week. This time I decided to increase the ppm up to 600 and see if the plant was going to sustain it. I was honestly expecting a small bite burn but it seems like nothing has happened after 3 days. Ph keeps increasing slightly everyday and ppm keeps decreasing. Really happy with how this is going.

Day 30 of flower; I raised her pot about 30 cm to get closer to the light and to prevent her younger tall neighbours from over-growing her. She's packed with deliciously smelling, very sticky buds. This is a true queen! One of the better, if not the best, smelling plant I've grown. Can't wait to try her. She'll be ready soon. 😊

the plants are not too leafy but still need a bit defoliation around week 3 and 6 of flower, depending on how u grow this ofcourse next time i would bend them more in the net. anyway the buds are rockhard even at the bottom where there was no light.

We’re done! Thanks a lot again to Zamnesia and Greenhouse, next big shoutout to Spiderfarmer and Biobizz. For further updates and more stuff hit me up with a follow on IG @herrnlubitz88 Stay tuned for next run!

Everything is looking good. Gave these girls a shot of recharge and fish shit. Prepping there new homes and getting ready to transplant.

Flowering Day 22 - They still growing very fast, the routine now is watering 3 times a week (2 with nutrients), on this week I add Azomite on soil, but they becoming thirst very fast. F Day 26 - Down leaves are becoming yellow very fast, I think Cinderella99 (the left one) Its more hungry. Water routine it is - 4 times a week, 3 with nutrientes (EC 1150), 1 only water, both pH 6.4 😁